#PAGE_PARAMS# #ADS_HEAD_SCRIPTS# #MICRODATA#

Herpes simplex encephalitis in adult patients with MASP-2 deficiency


Authors: Stéphanie Bibert aff001;  Jocelyne Piret aff002;  Mathieu Quinodoz aff003;  Emilie Collinet aff001;  Vincent Zoete aff004;  Olivier Michielin aff004;  Rafik Menasria aff002;  Pascal Meylan aff001;  Titus Bihl aff008;  Véronique Erard aff008;  Florence Fellmann aff009;  Carlo Rivolta aff003;  Guy Boivin aff002;  Pierre-Yves Bochud aff001
Authors place of work: Infectious Diseases Service, Department of Medicine, University Hospital and University of Lausanne, Lausanne, Switzerland aff001;  Research center in Infectious Diseases, CHU of Quebec and Laval University, Quebec city, Canada aff002;  Department of Computational Biology, Unit of Medical Genetics, University of Lausanne, Lausanne Switzerland aff003;  Ludwig Institute for Cancer research, University of Lausanne, Lausanne, Switzerland aff004;  Molecular Modeling Group, Swiss Institute of Bioinformatics, Quartier Sorge, Génopode, Lausanne, Switzerland aff005;  Department of Oncology, University Hospital and University of Lausanne, Lausanne, Switzerland aff006;  Institute of Microbiology, Department of Laboratory Medicine, University Hospital and University of Lausanne, Lausanne, Switzerland aff007;  Canton Hospital of Fribourg, Fribourg, Switzerland aff008;  Department of Genetics, Laboratoire National de Santé, Dudelange, Luxembourg aff009;  Department of Genetics and Genome Biology, University of Leicester, Leicester, United Kingdom aff010
Published in the journal: Herpes simplex encephalitis in adult patients with MASP-2 deficiency. PLoS Pathog 15(12): e32767. doi:10.1371/journal.ppat.1008168
Category: Research Article
doi: https://doi.org/10.1371/journal.ppat.1008168

Summary

We report here two cases of Herpes simplex virus encephalitis (HSE) in adult patients with very rare, previously uncharacterized, non synonymous heterozygous G634R and R203W substitution in mannan-binding lectin serine protease 2 (MASP2), a gene encoding a key protease of the lectin pathway of the complement system. None of the 2 patients had variants in genes involved in the TLR3-interferon signaling pathway. Both MASP2 variants induced functional defects in vitro, including a reduced (R203W) or abolished (G634R) protein secretion, a lost capability to cleave MASP-2 precursor into its active form (G634R) and an in vivo reduced antiviral activity (G634R). In a murine model of HSE, animals deficient in mannose binding lectins (MBL, the main pattern recognition molecule associated with MASP-2) had a decreased survival rate and an increased brain burden of HSV-1 compared to WT C57BL/6J mice. Altogether, these data suggest that MASP-2 deficiency can increase susceptibility to adult HSE.

Keywords:

Alleles – Sequence motif analysis – Cytokines – chemokines – Mouse models – complement system – Molecular dynamics – Lectins

Introduction

Herpes simplex virus encephalitis (HSE) is the most common cause of sporadic fatal viral encephalitis in Western countries with a mortality rate of ~70% in the absence of antiviral treatment [1]. It occurs in 2–4 individuals per million and per year, with a bimodal age distribution including children, mainly as a result of primary infection [2, 3], and adults over the age of 50 years, as a result of reactivation from a latent infection [4].

Studies mainly performed in children revealed that the TLR3 pathway is essential and non-redundant for induction of IFN-α, β, λ and γ in the central nervous system (CNS) [5] and that the pathogenesis of HSE and its recurrence may result from single-gene inborn errors of TLR3/IFN pathway-mediated immunity [614]. Most of these result from autosomal-dominant variants with incomplete clinical penetrance [15], highlighting the importance of environmental, pathogen and additional host factors. Rare variants in the TLR3/IFN signaling pathway have also been identified in adults [16] confirming that impaired TLR3-mediated immunity may also increase susceptibility to HSE in this population. Nevertheless, two studies in adult patients identified variants in genes not directly involved in the TLR3/IFN pathway, indicating that other genes/pathways may also be associated with the development of HSE [17, 18].

We report here 2 cases of adult HSE in patients with very rare variants in mannan-binding lectin serine protease 2 (MASP-2), the gene encoding a protease considered as the central activator of the lectin pathway of the complement system (the most ancient, besides the classical and alternate pathways of complement activation), because of its ability to form complexes with several pattern recognition molecules including mannose-binding lectin (MBL), collectins (CL-L1 and CL-K1) and ficolins (FCN1, FCN2 and FCN3 also called M-, L- and H-ficolin respectively).

Results

The presence of very rare and deleterious variants in innate immune genes was analysed in 15 HSE adult patients of European ancestry who did not present other unusual severe infectious diseases, compared to 294 controls of same ethnic background. Among the 950 innate immune genes tested, 33 presented at least one qualifying variant in one case of HSE and none was significant, following correction for multiple testing. However, we could identify 4 genes with suggestive evidence for enrichment, in qualifying variants in HSE cases vs. controls. None of these genes were related to the TLR3/IFN signaling pathway. We focused our analysis on one of them, namely the mannan-binding lectin serine protease 2 (MASP2).

MASP-2 is involved in the complement system as the central protein of the lectin pathway, which is triggered by specific recognition of pathogens. Notably, mice deficient in MASP2 or MBLs (two genes involved in the lectin pathway) were recently shown to have increased mortality compared to WT mice in a model of West Nile virus infection [19]. Specifically, two out of the 15 HSE individuals carried 2 different very rare and predicted to be deleterious variants compared to 5 of such variants in 294 controls (OR 8.26, individual P = 0.041). We confirmed the enrichment by comparing the same cases with gnomAD-NFE (Non-Finnish Europeans) and found a similar OR of 12.6 (p = 0.013). In contrast, no very rare non-synonymous variants in the MBL gene were observed among HSE cases. Because frequent MBL variants are strongly associated with lectin pathway activity, we compared their frequencies among HSE cases and controls. The proportion of frequent functional MBL variants (namely rs5030737, rs1800450, rs1800451, rs11003125, rs7096206, rs7095891 which form haplotypes HYPA, LYQA, LYPA, LXPA, HYPD, LYPB, LYQC, LYPD associated with low MBL serum concentration) was similar in both groups (OR = 0.83, 95% confidence interval 0.33–1.97, P = 0.8).

Among the two HSE adult patients who have non-synonymous rare variants in MASP2, one was a female patient (P1) carrying a heterozygous NM_006610.3:c.1900G>A (genome build hg19) mutation resulting in a replacement of a glycine residue to an arginine residue at amino acid position 634 (NP006601.2) within the serine protease domain (G634R, Fig 1A and 1C). Patient P1 was hospitalized at the age of 60 for a generalized tonico-clonic seizures shortly preceded by important occipital headache (Table 1). She had no relevant co-morbidity except splenectomy during her childhood. Cerebrospinal fluid (CSF) real-time PCR was positive for HSV-1[20]. Magnetic resonance imaging showed lesions in the right temporal lobe. P1 was treated with acyclovir within hours after the onset of clinical symptoms and had full clinical recovery. P1 is the only member of this family to have developed HSE. Noteworthy, a 20 year old female patient in our exome sequencing dataset also carried the G634R mutation. She was hospitalized for a primary attack of multiple sclerosis. The medical chart review revealed that her CSF was tested positive for HSV-1. Although the clinical presentation was not typical for HSE, the patient received acyclovir treatment to cover a potential early form of HSE.

Fig. 1. MASP2 mutations in HSE patients.
<i>MASP2</i> mutations in HSE patients.
A. and B. Sanger sequencing of PCR products amplified from genomic DNA from control and patients carrying the G634R (A) or the R203W (B) mutation. C. Schematic representation of MASP2 with exons (Ex) 1–12, zymogen and active protein featuring the different domains as well as the location of non-synonymous functional variants. MASP-2 is composed of well-defined domains comprising the CUB1 (C1r/C1s, Uegf and bone morphogenetic protein-1 domains), EGF (epidermal growth factor), CUB2, CCP1, CCP2 (complement control protein module 1 and 2) and serine protease. D. Experimental predicted 3D structure of MASP-2 in ribbon representation (PDB ID 1ZJK). The active catalytic triad Asp532, His483 and Ser633 is displayed in ball and stick. The backbone of residues 483, 532, 633 and 634 are colored in green. E. Last frame of one MD simulation of the G634R MASP-2 in the same orientation. Arg634 protrudes between His483 and Ser633, separating these two residues and impairing the catalytic triad.
Tab. 1. Clinical features in 2 HSE patients.
Clinical features in 2 HSE patients.

The second patient P2 had a NM_006610.3:c.607C>T heterozygous nucleotide replacement (Fig 1B) which results in the substitution of an arginine residue for a tryptophan residue at amino acid position 203 in the CUB2 domain (R203W, Fig 1B and 1C). P2 was a previously healthy 24 years old man who was hospitalized for fever with headaches, photophobia and vomiting. The patient already presented unusual headaches, nightmares and delusional ideas during the 5 days preceding hospitalization (Table 1). He developed a tonico-clonic seizures after lumbar puncture and subsequently underwent craniotomy due to cerebral herniation. He was treated with acyclovir. Real time CSF PCR was positive for HSV-1. Cranial imaging initially revealed a signal in the cortical region, with important right temporal oedema, which progressively evolved towards right cerebral ventricle dilatation. The patient had important neurological sequelae with severe neuropsychological impairment.

The G634R mutation (P1) is referenced in ExAC as rs532646305, with a MAF of 1.1x10-4 among non-finnish Europeans and is predicted to be deleterious by the Sorting Intolerant from Tolerant (SIFT) and Polymorphism Phenotyping 2 (PolyPhen-2) scores. Three and six Molecular Dynamic (MD) simulations were performed for the wild type and G634R MASP-2, respectively, each 140 ns in length. The MD simulations of the wild-type system showed that the catalytic triad D532, H483 and S633 appeared very stable, as could be expected. D532 accepted a strong and stable hydrogen bond from H483. The average minimal distance between the two residues in the last 50 ns of these MD simulations was 2.84 ± 0.02 Å. A weaker, yet stable, hydrogen bond also existed between S633 and H483, with an average minimal distance of 3.8 ± 0.3 Å over the last 50 ns of the 3 MD simulations. These three residues remained constantly in contact during the simulations (S1 Fig, S2 Fig). On the contrary, the MD simulations of the mutated MASP-2 consistently showed that the mutation of residue G634 to R disrupted the catalytic triad by projecting the new R634 side chain between S633 and H483 leading to a dramatic increase of the distance between S633 and H483 (6.0 ± 0.4 Å during the last 50 ns of the MD simulations) which may impair the activity of MASP-2 (Fig 1D and 1E).

The R203W mutation (P2) is referenced in ExAC as rs373318594, with a MAF of 1.3x10-4 among NFE and is predicted to be deleterious by SIFT and PolyPhen-2 scores. No experimental structure is available for MASP-2 between residues 181 and 287, preventing any precise and relevant MD simulations of the wild type and mutated proteins. Sequence alignment of MASP-2 from 19 organisms, including Homo sapiens, shows that R203 belongs to a very conserved motif 199-PEYPxPYPK-207. Although R203 is not itself conserved, it is only replaced by polar residues in other species (S3 Fig). This is perfectly in line with the experimental 3D structures of MASP-1 in this region (47.7% sequence identity with MASP-2), which shows that the PEYPxPYPK-like motif (i.e. 200-PDFPxPYPK-208 in MASP-1) is essential for the structure of the CUB2 domain. R203 of MASP-2 is replaced by N204 in MASP-1. The latter belongs to a loop, faces the solvent, and possibly makes a hydrogen bond with D201 (corresponding to E200 in MASP-2), explaining that this position should be occupied by a polar residue. Replacing R203 in the related position of MASP-2 by a bulky, non-polar and aromatic tryptophan residue is expected to impact the stability of this region (S4 Fig).

To biochemically characterize the heterozygous G634R and R203W variants, we cloned both wild-type and mutant cDNAs and expressed them in Hela cells, instead of directly using primary cells. The expression of MASP-2 in cell lysate (Fig 2A) and in the culture supernatant (Fig 2B) was analyzed by Western blotting. The precursor (zymogen) form of MASP-2 is represented by a 76kDa band. The active form is composed of two polypeptides linked by a disulfide bridge appearing as a single band (undistinguishable from zymogen) under non-reducing condition, and as two separate bands (a 52kDa A-chain and 24kDa B-chain) under reducing conditions. Since the epitope targeted by the Western blotting antibody was directed against the N-terminal part, both the zymogen and A chain, but not the B chain of MASP-2, could be detected. Under reducing conditions, the WT form of MASP-2 appeared as two bands in both the cell lysate and cell supernatant, suggesting that it is capable of auto-activation and can be secreted. In contrast, the G634R form appeared as a unique 76kDa band which is present in cell lysate, but not in cell supernatant, suggesting that it is not capable of self-activation and not secreted. As a control, under non-reducing conditions, the WT form appears as a unique 76kDa band (Fig 2C). Under reducing conditions, the R203W appears as two separate bands in cell lysate and cell supernatant, with lower intensity in the cell supernatant, suggesting that it is capable of self-activation, but is poorly secreted compared to the WT.

Fig. 2. Biochemical characterization of G634R and R203W MASP-2 proteins.
Biochemical characterization of G634R and R203W MASP-2 proteins.
A-C. The ability of G634R and R203W MASP-2 proteins to be expressed, secreted and to auto-activate was determined by SDS-PAGE/immunoblotting under reducing (A, B) and non-reducing conditions (C) in cell lysates (A) and cell supernatant (B, C). Binding to recombinant MBL was determined in cell lysates (D) and cell supernatant (E) by co-immunoprecipitation experiments by using an antibody directed against MBL (IP). Housekeeping proteins β actin and macrophage migration inhibitory factor (MIF) were used as loading controls for cell lysates and cell supernatant respectively.

To compare the ability of the WT and mutant forms of MASP-2 to bind to MBL, the main lectin pathway pattern recognition molecules, lysates of cells expressing the WT and mutant forms were mixed with those expressing MBL. Complexes were then co-immunoprecipitated under non- reducing conditions with a MBL antibody. Both the WT and the G634R were capable to bind MBL expressed in cell lysates. Binding was observed for both the zymogen and the A-chain in the WT form of MASP-2, but only for the zymogen form of the G634R variant, further confirming its inability to auto-activate (Fig 2D). In addition, MBL binding in supernatant was observed for the WT and the R203W variant of MASP-2, but not the G634R form, as a probable result of its reduced or abolished secretion (Fig 2E). Altogether, these observations suggest that the G634R and R203W forms of MASP-2 are both expressed and capable to bind MBL. Compared to WT form, the secretion of R203W is reduced, and that of G634R is almost abolished. In addition, the R203W form has a conserved ability to auto-activate, a capacity which is totally lost for G634R.

To functionally characterize the consequence of heterozygous G634R carriage in vivo, the levels of MASP-2 (Fig 3A) and the MASP-2 activity of the MBL/MASP-2 pathway of the complement (Fig 3C) were analysed in plasma from G634R heterozygous carriers (N = 4) and WT controls (N = 8). MBL/MASP-2-induced complement activation was measured by the ability of plasma from G634R and WT individuals to deposit C4b on mannan-coated microtiter wells. In order to avoid a bias due to differential MBL expression, each G634R carrier was individually matched with 2 WT controls having comparable MBL levels (+/- 50ng/ml, Fig 3B). As ficolins do not bind to mannan, all changes in the amount of C4 cleavage depends on MASP-2. We observed that the level of MASP-2 and C4b deposition activity of the MBL/MASP-2 complexes were both significantly lower in G634R individuals compared to WT individuals. In order to analyse the antiviral role of MASP-2, we measured titers of HSV-1 after incubation of the virus with plasma from G634R individuals and WT individuals (Fig 3D). Plasma was previously depleted from antibodies in order to measure the direct effect of MASP-2 on HSV-1 neutralization [21] and to account for the absence of antibodies in non-inflamed meninges [22]. Plasma from heterozygous G634R carriers had a significant decreased ability to neutralize HSV-1 compared to plasma from WT controls. Thus, heterozygosity for the G634R MASP2 allele confers autosomal dominant hyporesponsiveness to HSV-1 in plasma.

Fig. 3. Functional characterization of G634R MASP-2 proteins.
Functional characterization of G634R MASP-2 proteins.
A. MASP-2 amount was evaluated in plasma of patient/family individuals carrying the G634R mutation (N = 4) as well as in WT individuals (N = 8). Each G634R individual was individually matched with 2 WT individuals having similar MBL levels (B) and the activity of MBL/MASP-2 complexes was determined by ELISA (C). D. Virus neutralization assay on plasma from both G634R and WT individuals. Virus titer determination was based on the presence of cytopathic effects on Vero cells. Statistical analyses were performed using an unpaired Student t-test.

MASP-2 is considered as the central activator of the lectin pathway of the complement system. To evaluate the role played by the lectin pathway in the pathogenesis of HSE, we used a murine model induced by intranasal HSV-1 injection. The survival of WT C57BL/6J mice was compared to that of mice deficient in MBL (MBL-null), as a surrogate marker for the MASP-2-dependent complement activation. MBL-null mice had significantly lower survival rates than WT mice (P = 0.04, Fig 4A, S5 Fig) suggesting that the lectin pathway is important for survival of infected mice. The role of the lectin pathway in controlling viral replication during HSE was further evaluated by measuring the viral DNA load in brain homogenates (Fig 4B). The viral genome copies were significantly higher in brain homogenates of MBL-null than in WT animals on day 5 (P = 0.03), which corresponds to the peak of infection, but not on day 7 post-infection (P = 0.35). This suggests that the lectin pathway contributes to control HSV replication during HSE. This was confirmed by the expression level of IFN-α which tended to be higher on days 5 and 7 post-infection (P = 0.06) (Fig 4C) and that of IFN-β which was significantly increased compared to WT on day 5 (P = 0.04) but not on day 7 post-infection (P = 0.06, Fig 4D). Altogether, these data suggest that the MBL/lectin pathway contributes to HSV-1 immunity in brain.

Fig. 4. Impact of MBL deficiency in HSV-1 infected mice.
Impact of MBL deficiency in HSV-1 infected mice.
A. Survival rates of WT and MBL-null (dotted line) mice. Results represent combined data from two separate experiments with 10 WT and 10 MBL-null mice each. Statistical analyses were performed using a log-rank (Mantel-Cox) test. B. Viral load in brain homogenates of WT (white) and MBL-null (black) mice. Results are mean ± standard error of the mean of 3–5 mice per group and per time-point. Statistical analyses were performed using an unpaired Student t-test. C, D. IFNα (C) and IFNβ (D) mRNA levels normalized to those of 18S mRNA, in brain homogenates of WT (white) and MBL-null (black) mice on days 0, 5 and 7 post-infection. Results represent the mean ± standard error of the mean of 3–5 mice per group and per time point. Statistical analyses were performed using an unpaired Student t-test. A.U. stands for arbitrary units.

The inflammatory response among WT and MBL-null mice was compared by measuring pro-inflammatory (IL-1α, IL-1β, IL-6, IL-12p40 and TNF-α) and anti-inflammatory cytokines (IL-10, IL-13 and G-CSF, Fig 5) and chemokines (CCL2, CCL3, CCL4, CCL5 and CXCL1, Fig 6) levels in brain homogenates at different time points after HSV-1 infection. The levels of several pro-inflammatory cytokines (IL-1α, IL-1β, IL-6 and IL-12p40) and chemokines (CCL2, CCL3, CCL4 and CCL5), including agents with a neurotrophic or neuroprotective potential (G-CSF and CXCL1) were significantly increased in MBL-null mice compared to WT on day 5 post-infection (all P<0.05). There was no statistical differences between brain cytokines and chemokines levels on day 7 post-infection. No changes were observed in the levels of the anti-inflammatory cytokines (IL-10 and IL-13) and the pro-inflammatory cytokines TNF-α in brain homogenates of WT and MBL-null mice after infection with HSV-1 (Fig 5). Altogether, the increased brain viral load observed on day 5 post-infection in MBL-null mice may lead to an exaggerated inflammatory response.

Fig. 5. Impact of MBL deficiency on levels of cytokines in brain homogenates of mice infected with HSV-1.
Impact of MBL deficiency on levels of cytokines in brain homogenates of mice infected with HSV-1.
Levels of cytokines were measured by magnetic bead-based immunoassay in brain homogenates of WT (white) and MBL-null (black) mice. Results represent the mean ± standard error of the mean of 3–5 mice per group and per time point. Statistical analyses were performed using an unpaired Student t-test.
Fig. 6. Impact of MBL deficiency on levels of chemokines in brain homogenates of mice infected with HSV-1.
Impact of MBL deficiency on levels of chemokines in brain homogenates of mice infected with HSV-1.
Levels of chemokines were measured by magnetic bead-based immunoassay in brain homogenates of WT (white) and MBL-null (black) mice. Results represent the mean ± standard error of the mean of 3–5 mice per group and per time point. Statistical analyses were performed using an unpaired Student t-test.

Discussion

In this study, we report two cases of adult HSE occurring in patients carrying very rare variants in MASP-2, a key protease in the lectin pathway of the complement system. A number of studies have shown that the complement is an important component of immune defences against HSV-1 [23, 24]. Deficiencies in different proteins of the complement such as C3 and C4 have been associated with impaired viral neutralization and reduced antibody production in mouse models of HSV-1 infection [25, 26]. Furthermore, it was clearly demonstrated that HSV-1 has developed escape strategies to avoid its neutralization by complement proteins [27]. Escape from the classical pathway occurs through an HSV-1 encoded receptor for the Fc domain of IgG (FcγR) which protects the virus from antibody-dependent complement neutralization [28]. Escape from the alternative pathway occurs through the HSV-1 encoded glycoprotein gC which protects the virus from destruction by complement in vitro [2932] as well as in guinea pig models [33].

Fewer studies analysed the role of the lectin pathway in HSV-1 detection. The lectin pathway activity is triggered by recognition of mannan and carbohydrate structures present on surface of invading microorganisms [3335] by pattern recognition receptors such as mannose-binding lectin, ficolins (L-ficolin, M-ficolin, H-ficolin) or collectins (CL-10 and CL-11), in complexes with MBL-associated serine protease 2 [3638]. Specifically, MBL-1 and/or MBL-2 are capable to recognize structures present on HSV-1, as demonstrated in experiments using serum from mice and rats [39]. MASP-2 represents the enzymatic constituent of the lectin pathway and plays a fundamental role in both C4 and C2 cleavage [40].

Variants in MASP2 leading to functional deficiencies have been reported [41, 42] but their association with diseases so far have been subject of controversy [41, 4347]. In humans, relatively common polymorphisms within genes involved in the lectin pathway were associated with infectious and autoimmune diseases [43, 4851]. Due to the ability of MBL to bind to a broad variety of fungi, bacteria and viruses, the lectin pathway contributes to different infections, pathogenesis and disease severity in mice [19, 52] and humans [53, 54]. Complement proteins are constitutively synthesized by different cells of the CNS including cells of the blood brain barrier (BBB), neurons and glial cells [5557]. Since the CNS is considered to be an immune-privileged site, separated from circulating plasma complement components by the BBB, local complement proteins may be particularly relevant to viral immunity in the brain. The lectin complement pathway may be critical for HSV-1 immune detection, as an immune mediator whose specific role becomes obvious when other potentially redundant effectors are missing, as it is the case in chemotherapy-related neutropenic patients [58] or in newborns [59, 60]. This may be particularly relevant during the early steps of infection when the permeability and the integrity of the BBB is not compromised, still preventing penetration of antibodies into the CNS compartment.

The mutations observed in our adult HSE patients were associated with an abnormal protein secretion, a lost ability of auto-activation (G634R) and a reduced antiviral activity (G634R). At the population level, the proportion of very rare variants in MASP2 was enriched among HSE patients compared to controls. By using a relevant intranasal HSE model [61], we showed that mice deficient in MBL had lower survival rates, higher viral load and a faster increase in the levels of cytokines and chemokines in the brain compared to WT mice. Murine models of HSE that consist in a primary and acute infection may not accurately reflect the pathology in humans (which is mainly due to virus reactivation). However, these data suggest that a deficiency in the lectin pathway results in a lack of control of viral replication leading to an exacerbated inflammatory response in the brain, that results in an increased mortality rate in mice infected with HSV-1. The mouse model of intranasal infection used in this study is not expected to induce HSV-1 viremia and spread to internal organs in WT animals [62, 63]; yet, one cannot exclude that such spread would have been observed in MBL deficient mice. MASP-2 deficient mice were protected by a patent and not available for this study, so that MBL-A x MBL-C deficient mice (only one MBL gene is expressed in humans whereas two closely related proteins MBL-A and MBL-C are produced in mice) were used instead of MASP-2 deficient mice to test the role of the lectin pathway in susceptibility to HSE. Since MBL is one of several pattern-recognition molecules associated with MASP-2, we believe that our experiment may have at worst underestimated the role of this pathway in susceptibility to HSE. Thus, the increased mortality observed in MBL-null mice compared to WT animals further confirms the protective role of the lectin pathway against HSE.

Previous studies mainly performed in children have shown that HSE is linked with mutations in genes involved in the TLR3/IFN immune pathway [1017, 64, 65]. The role of this pathway is further supported in intranasal models of HSE using mice deficient in TRIF (the TLR3 adaptor [66]), Unc93B (protein involved in TLR3, TLR7 and TLR9 sorting [67]) and the IFN-α receptor [67]. Since HSE patients were relatively resistant to infectious diseases outside the CNS [68, 69], the TLR3/IFN pathway was proposed to be essential and non-redundant for CNS immunity against HSV-1 [70]. Yet, increasing evidences suggest that variants in immune pathways other than the TLR3-IFN axis may contribute to HSE [63, 71]. Functional impairment in the TLR3-IFN pathway could explain susceptibility to HSE in only 5% of affected children [15], in particular those with HSE recurrence, suggesting that other immune pathways may be involved in susceptibility to HSE in children. This may be even more relevant for adult patients, as HSE mainly results from reactivation of a latent virus in trigeminal ganglia neurons [3] contrasting with children where disease usually results from primary infection. Indeed, mutations in Tyrosine Kinase 2 (TYK2, [17]), Mitochondrial antiviral signaling protein (MAVS, [17]) have recently been described in adult HSE patients.

Altogether, this study shows that rare variants in MASP-2 may increase susceptibility to HSE, thereby suggesting that HSE does not solely result from mutations in genes of TLR3-IFN pathway. Further studies showing additional HSE-associated variants in the lectin pathway would reinforce these observations, as the disease in adults may result from a combination of conditions including genetic or acquired immune deficiency, timing of infection/reactivation and environmental factors.

Material and methods

Ethics statement

Patients and healthy volunteers included in this study signed an informed consent form for genetic and functional testing. The study was approved by the Cantonal Ethics Committee of the state of Vaud (CER-VD #130/08). All animals were used in accordance to the Canadian Council on Animal Care guidelines and the protocol was approved by the Animal Care Ethics Committee of Laval University (protocol no. 2013078).

Study patients

A total of 15 pure European ancestry patients with a positive PCR for HSV-1 and signs/symptoms of HSE were included in the study. Samples from an additional patient with multiple sclerosis and family members (see results section) were included in functional experiments, allowing for G634R characterization in a total of 4 heterozygous carriers.

MBL genotyping

Polymorphisms in the MBL promoter region (rs11003125 or H.L variant, rs7096206 or X, Y variant and rs7095891 or P, Q variant) were determined by sequencing PCR-amplified gDNA loci. Variants located in the first exon of the gene (rs5030737 or R52C or variant allele D, rs1800450 or G54D or variant allele B, rs1800451 or G57E or variant allele C) were determined by exome sequencing. The D, B and C variant alleles were collectively called O and the major alleles at these loci named A. The O indicated the presence of one or more mutant allele(s) in any of the 3 polymorphisms.

Whole exome sequencing

Genomic DNA was extracted from venous blood samples of 15 cases of adult with HSE and 1 case of adult MS, all of pure European ancestry. Construction of paired-end sequence libraries and exome capture were performed by using 50Mb Agilent SureSelect Capture Kit. Captured libraries were sequenced on an Illumina platform as paired-end 54-bp reads according to the manufacturer's protocol. The purity filtered reads from the standard Illumina processing pipeline were aligned to the NCBI37 human reference genome using Novoalign (V3.08.00, Novocraft Technologies Sdn Bhd, Selangor, Malaysia), generating a binary alignment map (BAM) file per sample for each aligner. Single nucleotide variants (SNVs) and indels were called using the genome analyzer toolkit (GATK) v3.8 [72] and filtered using a minimum read depth (>10), minimum genotype quality (GQ>50), minimum alternative allele ratio (>0.3), minimum quality by depth (QD>5) and maximum FisherStrand (FS<60).

Gene-burden analysis

Individuals of non-Finnish European (NFE) ancestry (15 cases and 294 in-house controls) were identified by using the Ethseq software [73]. Rare and deleterious variants were selected according to the following criteria: (i) allele frequency <0.001, as reported in the ExAC-NFE and gnomAD-NFE, (ii) nonsynonymous effect on the predicted protein product (missense, nonsense, frameshift, or essential splicing), and (iii) combined annotation dependant (CADD) score higher than 20 (representing the top 1% most deleterious variants according to the predictor, https://cadd.gs.washington.edu/info). A gene burden test was then performed in cases vs controls, by focusing on genes involved in innate immune response (gene ontology term GO:0045087) and by using the Fisher’s exact test to compute every associated p-value. Enrichment versus gnomAD-NFE population was done using variants selected by the same criteria as described above and Fisher's exact test was performed on an estimated gnomAD-NFE population of 60.000 individuals. Common MBL2 variants NM_000242.2:c.C154T:p.R52C, NM_000242.2:c.G161A:p.G54D and NM_000242.2:c.G170A:p.G57E were analysed. Analysis on genes related to the TLR3/IFN pathway concentrated on UNC93B1, TLR3, TICAM1, TBK1, TRAF3, STAT1 and IRF3.

Molecular dynamics simulations

MD simulations were performed with GROMACS [74, 75] version 2018.3 in periodic boundary conditions, using the all-atom CHARMM27 force field [76] and the TIP3P water model. The number of Na+ and Cl- ions in solution was adjusted to neutralize the system and reach the physiological concentrations of 0.154 M. Before starting the MD simulations, missing residues and loops were modelled using the Dunbrack rotamer libraries [77] and the Modeller program [78]. Titratable side chains were protonated so as to allow hydrogen bonds with neighbouring residues. Electrostatic interactions were calculated with the Ewald particle-mesh method with a grid spacing of 1.2 Å. A cut-off of 12 Å was applied for the real-space Coulomb and van der Waals interactions. Bonds involving hydrogen atoms were constrained using the P-LINCS algorithm [75].The system was coupled to a Parinello-Rahman barostat with a relaxation time of 1 ps. The solute and the solvent were separately coupled to two nose-hoover thermostats, each with a relaxation time of 0.2 ps. A time integration step of 2 fs was used, with a temperature of 300 K and a pressure of 1 bar during the production trajectory. Initial structures were taken from the experimental 3D structure of the zymogen catalytic region of human MASP-2 (PDB ID 1ZJK [79]). Mutation G634R was introduced using the swapaa command of UCSF Chimera [80] v 1.12 and the Dunbrack backbone-dependent rotamer library [77]. Initial structures were energy optimized, heated from 0 to 300 K in 0.4 ns, equilibrated for a further 1 ns restraining each solute non-hydrogen atom to its original position, and finally equilibrated for 2 ns without restraints before data collection. Three and 6 MD simulations were carried out for the WT and mutated MASP-2, respectively, to assess the reproducibility of the results. Each MD simulation had a production time of 140 ns, saving coordinates every 0.05 ns.

Production of recombinant proteins

The human MBL as well as the WT and mutant MASP-2 cDNAs were amplified by PCR from total RNA isolated from whole blood. Purified products were subcloned into a pGEM-T Easy vector by T4 DNA ligase (Promega) and sequenced. We generated pcDNA3.1 expression vectors (Thermofisher) encoding the different MASP-2 variants and MBL. Plasmids containing cDNAs were used for the transient transfection of Hela cells. Briefly, plasmids were mixed with JetPei (Polyplus transfection, USA), according to the manufacturer’s instructions. Cells were cultured for 24 h, 48 h or 72 h in a medium deprived in Fetal Calf Serum (FCS). Supernatants were collected by centrifugation at 10,000 xg, 5 min, 4°C and cells were lysed with a lysis buffer containing Tris 10 mM, pH 8, NaCl 150 mM, NP-40 0.5%, NaF 10 mM, Na-orthovanadate 1 mM and protease inhibitors and collected by centrifugation at 10,000 xg, 5 min, 4°C.

Expression of recombinant proteins

Cells were washed 2 times with phosphate-buffered saline (PBS), harvested with the lysis buffer previously described and centrifuged at 10,000 xg at 4°C, 5 min. For some experiments, cell culture supernatants were concentrated on Microcon concentration units (Amicon, Merck). Protein content was determined by the Biorad Protein assay (Biorad). Proteins (20 μg-40 μg) were then subjected to SDS-PAGE under reducing and non- reducing conditions and then transferred onto a nitrocellulose membrane. The rabbit anti-human MASP-2 H-60 antibody (1/200, sc-50420, Santa Cruz Biotechnology), rabbit anti-human MBL-2 antibody (1/1,000, orb 31822 Biorbyt), rabbit anti-human macrophage migration inhibitory factor (MIF) antibody [81] and mouse anti-B actin antibody (1/1,000, sc-8432, Santa Cruz Biotechnology) were used as primary antibodies and were detected using anti-rabbit or mouse IgG antibodies conjugated to horseradish peroxidase (1/10,000, Amersham Biosciences). Detection was done with the ECL chemiluminescence kit (Pierce) according to the manufacturer’s protocol.

MASP-2 dosage

MASP-2 concentrations were measured in the plasma, cell lysates or cell culture supernatants using enzyme-linked immunosorbent assay (HK326, Hycult biotechnology, Uden, The Netherlands) according to the manufacturer’s instructions.

MBL/MASP-2 dosage

The in vitro quantitative determination of functional human MBL/MASP-2 in the plasma was measured by enzyme-linked immunosorbent assay (HK327, Hycult biotechnology, Uden, The Netherlands) according to the manufacturer’s instructions. This assay quantifies the ability of MBL/MASP-2 complexes to initiate C4 cleavage when bound to mannan.

Immunoprecipitation

Supernatants from WT- or mutant MASP-2-expressing cells were mixed with an equal volume of supernatants from MBL-expressing cells. After 5 h incubation in a buffer containing Tris 25mM, pH 8, NaCl 150mM, CaCl2 5mM, at 4°C, immunoprecipitation of MBL under non-denaturing conditions was performed with 3 μl of mouse anti-human MBL2 antibody (ab26277, abcam). Proteins were then resolved by SDS-PAGE and then transferred onto a nitrocellulose membrane. The association of MASP-2 was revealed by using a rabbit anti-human MASP-2 H-60 antibody (1/200, sc-50420, Santa Cruz Biotechnology). The expression of MBL was also determined with a rabbit anti-human MBL-2 antibody (1/1,000, orb 31822 Biorbyt).

HSV-1 amplification

Human herpesvirus 1 strain MacIntyre used in viral neutralization studies was purchased from ATCC (ATCC VR-539) and was amplified on a 80% confluency African green monkey kidney (Vero) cell line in DMEM/GlutaMax supplemented with 10% FBS. Briefly, Vero cells were infected with HSV-1 at a multiplicity of infection of 0.01, during at least 2h at 37°C. Medium was then replaced and supernatant was collected after 4 days incubation at 37°C and clarified at 4,500 xg for 30 min. HSV-1 titers were determined by plaque assay on Vero cells and virus preparation was aliquoted and stored at -80°C.

Plaque assay

Different dilutions of HSV-1 suspension were incubated on Vero cells during at least 2h at 37°C. Supernatant was then aspirated and cells washed with PBS. Cells were then incubated in DMEM containing 1% MethylCellulose and 0.33% Sodium Bicarbonate at 37°C for several days, until the plaque formation. Medium was then aspirated and the cells were fixed and stained with a mixture of Paraformaldehyde 2% and crystal violet 0.5% for 15 min at room temperature. HSV-1 titre was evaluated from plaque counting and expressed as PFU/ml.

Antibodies deprived plasma

Plasma samples were 2-fold diluted in Sodium phosphate 20mM, pH 7 and added to protein G HP SpinTrap columns (GE Healthcare life Sciences, United Kingdom) according to the manufacturer’s instructions. Antibodies were attached to the Protein G Sepharose and flow-through containing antibodies deprived plasma was collected and immediately stored at 4°C.

HSV-1 neutralization

Antibodies deprived plasma were mixed with different dilutions of HSV-1 during 20 min at 37°C. The mixture was then incubated on Vero cells during at least 2h at 37°C and the neutralizing activity of plasma was determined using a plaque assay on Vero cells.

Animals

Mice homozygous for MBL-AxMBL-C knockout mutations (MBL-null; B6.129S4-Mbl1tm1Kata Mbl2tm1Kata/J) and wild-type C57BL/6J mice were purchased from Jackson Laboratory (Bar Harbour). Animals were housed three to five per cage and acclimated to standard laboratory conditions for one week.

In two sets of experiments, 10 MBL-null and 10 WT C57BL/6J male mice at 6–7 weeks of age were infected intranasally with 700,000 PFUs of the neurovirulent clinical HSV-1 strain H25 in 20 μl of minimal essential medium (MEM) [61]. Mice were monitored for weight loss, neurological signs (shaking movement, hind limb paralysis, prostration and convulsion), ruffled fur, ocular swelling and survival rate over 18 days. Animals were sacrificed when a weight loss equal to or greater than 20% or a combination of two other obvious sickness signs were recorded. The results of the two experiments were pooled for analysis.

In a third set of experiments, MBL-null and WT C57BL/6J male mice at 6–7 weeks of age were infected intranasally with 700,000 PFUs of HSV-1 strain H25 in 20 μl of MEM. Mice were sacrificed prior to infection (day 0; n = 3 for both mouse strains) and on days 5 (n = 5 for both mouse strains) and 7 (n = 4 for both mouse strains) post-infection. Mice were euthanized and sacrificed by intracardiac perfusion with cold 0.9% saline. Brain was harvested and homogenized in 700 μl PBS containing protease and phosphatase inhibitor cocktails (Roche diagnostics) with a homogenizer (BioSpec Products, Inc.). For quantitative RT-PCR determinations of IFN-α/–β mRNA levels, 100 μl of brain homogenate were added to 1 ml of TRIzol reagent (Invitrogen). All samples were maintained on dry ice and stored at -80°C until used.

Total DNA was extracted from 10 mg of brain homogenates with the MagNA Pure LC DNA Isolation Kit II (Tissue; Roche Molecular Systems) according to the instructions of the manufacturer and eluted in 200 μl of elution buffer. Real-time qPCR assay was performed in duplicate using 5 μl of extracted total DNA mixed with LightCycler 480 Probes Master on a LightCycler 480 system (both from Roche Molecular System) and external standards were run in parallel as previously described [82]. Primers and probes targeted a conserved region of the DNA polymerase of HSV-1. The limit of detection of the assay is 200 copies of viral genome/mg of brain.

Brain homogenates were centrifuged at 10,000 xg for 10 min at 4°C. A volume of 50 μl of supernatant was taken for the determination of cytokine and chemokine levels using a commercial multiplex mouse cytokine magnetic bead-based immunoassay (Bio-Plex Pro Mouse Cytokine 23-plex Assay; Bio-Rad Laboratories) according to the manufacturer’s instructions. Mean fluorescence intensity from all the bead combinations tested was analyzed by the Bio-Plex Manager Software v6.0 (Bio-Rad Laboratories).

For the determination of IFN-α/–β transcripts by RT-qPCR, total RNA was extracted from brain homogenates using Direct-zol RNA MiniPrep Plus Kit (Zymo Research Corporation) as described in the manufacturer’s instructions. Complementary DNAs were generated using a random primer hexamer (Invitrogen) and the SuperScript II polymerase (Invitrogen). Amplicons were detected using the Amplifluor Uniprimer system in which forward primers contained the 5’ Z sequence ACT-G-A-A-C-C-T-G-A-C-C-G-T-ACA. Amplification efficiencies were validated and normalized to that of the 18S ribosomal subunit gene. The different forward and reverse primers used are described in S1 Table. Real-time qPCR was performed in 50 μl volume containing 25 μl of 2x Universal PCR Master Mix (Applied Biosystems), 10 nmol/l of Z-tail forward primer, 100 nmol/l of untail reverse primer (both from Integrated DNA Technologies), 100 nmol/l of Amplifluor Uniprimer probe (Sigma-Aldrich). The mixture was incubated at 50°C for 2 min, at 95°C for 4 min and then cycled 55-times at 95°C for 15 s and at 55°C for 40 s using the Applied Biosystems prism 7900 Sequence Detector (Applied Biosystems). An external standard was run in parallel.

Differences in mouse survival rates were compared using a log-rank (Mantel-Cox) test. Differences in viral load, cytokine and chemokine production and IFN-α/–β mRNA levels were evaluated using an unpaired Student t-test. All statistical analyses were performed using GraphPad Prism software program v5 (GraphPad Software, San Diego, CA). A P value ≤ 0.05 was considered as statistically significant.

Supporting information

S1 Fig [tif]
Running average of the minimal distance between His483 and Asp532, during the production part of the 3 MD simulations of the wild-type system (in blue) and the 6 MD simulations of the G634R mutant (in brown).

S2 Fig [tif]
Running average of the minimal distance between His483 and Ser633, during the production part of the 3 MD simulations of the wild-type system (in blue) and of the 6 MD simulations of the G634R mutant (in brown).

S3 Fig [tif]
Sequence alignment of MASP-2 from 19 organisms, in the region of Arg203.

S4 Fig [tif]
Experimental structure of the EGF-like and CUB2 domains of MASP-1 (PDB ID 4AQB) [PMID: 22854970].

S5 Fig [tif]
Survival rates of WT and MBL-null (dotted line) mice.

S1 Table [pdf]
Sequence of forward and reverse primers used to determine the levels of IFN-α/- β mRNAs by RT-qPCR.


Zdroje

1. Piret J, Boivin G. Innate immune response during herpes simplex virus encephalitis and development of immunomodulatory strategies. Reviews in medical virology. 2015;25(5):300–19. Epub 2015/07/25. doi: 10.1002/rmv.1848 26205506.

2. Koskiniemi M, Piiparinen H, Mannonen L, Rantalaiho T, Vaheri A. Herpes encephalitis is a disease of middle aged and elderly people: polymerase chain reaction for detection of herpes simplex virus in the CSF of 516 patients with encephalitis. The Study Group. J Neurol Neurosurg Psychiatry. 1996;60(2):174–8. Epub 1996/02/01. doi: 10.1136/jnnp.60.2.174 8708648; PubMed Central PMCID: PMC1073799.

3. De Tiege X, Rozenberg F, Heron B. The spectrum of herpes simplex encephalitis in children. Eur J Paediatr Neurol. 2008;12(2):72–81. Epub 2007/09/18. doi: 10.1016/j.ejpn.2007.07.007 17870623.

4. Whitley RJ, Gnann JW. Viral encephalitis: familiar infections and emerging pathogens. Lancet. 2002;359(9305):507–13. Epub 2002/02/21. doi: 10.1016/S0140-6736(02)07681-X 11853816.

5. Zhang SY, Herman M, Ciancanelli MJ, Perez de Diego R, Sancho-Shimizu V, Abel L, et al. TLR3 immunity to infection in mice and humans. Current opinion in immunology. 2013;25(1):19–33. Epub 2013/01/08. doi: 10.1016/j.coi.2012.11.001 23290562; PubMed Central PMCID: PMC3594520.

6. Dupuis S, Jouanguy E, Al-Hajjar S, Fieschi C, Al-Mohsen IZ, Al-Jumaah S, et al. Impaired response to interferon-alpha/beta and lethal viral disease in human STAT1 deficiency. Nat Genet. 2003;33(3):388–91. doi: 10.1038/ng1097 12590259

7. Niehues T, Reichenbach J, Neubert J, Gudowius S, Puel A, Horneff G, et al. A NEMO-deficient child with immunodeficiency yet without anhidrotic ectodermal dysplasia. J Allergy Clin Immunol. 2004;114:1456–62. doi: 10.1016/j.jaci.2004.08.047 15577852

8. Puel A, Reichenbach J, Bustamante J, Ku CL, Feinberg J, Doffinger R, et al. The NEMO Mutation Creating the Most-Upstream Premature Stop Codon Is Hypomorphic Because of a Reinitiation of Translation. Am J Hum Genet. 2006;78(4):691–701. doi: 10.1086/501532 16532398.

9. Audry M, Ciancanelli M, Yang K, Cobat A, Chang HH, Sancho-Shimizu V, et al. NEMO is a key component of NF-kappaB- and IRF-3-dependent TLR3-mediated immunity to herpes simplex virus. The Journal of allergy and clinical immunology. 2011;128(3):610–7 e1-4. Epub 2011/07/05. doi: 10.1016/j.jaci.2011.04.059 21722947; PubMed Central PMCID: PMC3164951.

10. Casrouge A, Zhang SY, Eidenschenk C, Jouanguy E, Puel A, Yang K, et al. Herpes simplex virus encephalitis in human UNC-93B deficiency. Science. 2006;314(5797):308–12. Epub 2006/09/16. doi: 10.1126/science.1128346 16973841.

11. Zhang SY, Jouanguy E, Ugolini S, Smahi A, Elain G, Romero P, et al. TLR3 deficiency in patients with herpes simplex encephalitis. Science. 2007;317(5844):1522–7. Epub 2007/09/18. doi: 10.1126/science.1139522 17872438.

12. Guo Y, Audry M, Ciancanelli M, Alsina L, Azevedo J, Herman M, et al. Herpes simplex virus encephalitis in a patient with complete TLR3 deficiency: TLR3 is otherwise redundant in protective immunity. The Journal of experimental medicine. 2011;208(10):2083–98. Epub 2011/09/14. doi: 10.1084/jem.20101568 21911422; PubMed Central PMCID: PMC3182056.

13. Sancho-Shimizu V, Perez de Diego R, Lorenzo L, Halwani R, Alangari A, Israelsson E, et al. Herpes simplex encephalitis in children with autosomal recessive and dominant TRIF deficiency. J Clin Invest. 2011;121(12):4889–902. Epub 2011/11/23. doi: 10.1172/JCI59259 22105173; PubMed Central PMCID: PMC3226004.

14. Herman M, Ciancanelli M, Ou YH, Lorenzo L, Klaudel-Dreszler M, Pauwels E, et al. Heterozygous TBK1 mutations impair TLR3 immunity and underlie herpes simplex encephalitis of childhood. The Journal of experimental medicine. 2012;209(9):1567–82. Epub 2012/08/02. doi: 10.1084/jem.20111316 22851595; PubMed Central PMCID: PMC3428952.

15. Lim HK, Seppanen M, Hautala T, Ciancanelli MJ, Itan Y, Lafaille FG, et al. TLR3 deficiency in herpes simplex encephalitis: high allelic heterogeneity and recurrence risk. Neurology. 2014;83(21):1888–97. doi: 10.1212/WNL.0000000000000999 25339207; PubMed Central PMCID: PMC4248460.

16. Sironi M, Peri AM, Cagliani R, Forni D, Riva S, Biasin M, et al. TLR3 Mutations in Adult Patients With Herpes Simplex Virus and Varicella-Zoster Virus Encephalitis. J Infect Dis. 2017;215(9):1430–4. Epub 2017/04/04. doi: 10.1093/infdis/jix166 28368532.

17. Mork N, Kofod-Olsen E, Sorensen KB, Bach E, Orntoft TF, Ostergaard L, et al. Mutations in the TLR3 signaling pathway and beyond in adult patients with herpes simplex encephalitis. Genes Immun. 2015;16(8):552–66. Epub 2015/10/30. doi: 10.1038/gene.2015.46 26513235.

18. Abdelmagid N, Bereczky-Veress B, Atanur S, Musilova A, Zidek V, Saba L, et al. Von Willebrand Factor Gene Variants Associate with Herpes simplex Encephalitis. PLoS One. 2016;11(5):e0155832. Epub 2016/05/26. doi: 10.1371/journal.pone.0155832 27224245; PubMed Central PMCID: PMC4880288.

19. Fuchs A, Pinto AK, Schwaeble WJ, Diamond MS. The lectin pathway of complement activation contributes to protection from West Nile virus infection. Virology. 2011;412(1):101–9. Epub 2011/01/29. doi: 10.1016/j.virol.2011.01.003 21269656; PubMed Central PMCID: PMC3057364.

20. Meylan S, Robert D, Estrade C, Grimbuehler V, Peter O, Meylan PR, et al. Real-time PCR for type-specific identification of herpes simplex in clinical samples: evaluation of type-specific results in the context of CNS diseases. Journal of clinical virology: the official publication of the Pan American Society for Clinical Virology. 2008;41(2):87–91. Epub 2007/11/27. doi: 10.1016/j.jcv.2007.10.010 18037340.

21. Friedman HM, Wang L, Pangburn MK, Lambris JD, Lubinski J. Novel mechanism of antibody-independent complement neutralization of herpes simplex virus type 1. J Immunol. 2000;165(8):4528–36. Epub 2000/10/18. 11035093.

22. Ledford H. Engineered antibodies cross blood–brain barrier. Nature. 2011. doi: 10.1038/news.2011.319

23. Daniels CA, Borsos T, Rapp HJ, Snyderman R, Notkins AL. Neutralization of sensitized virus by purified components of complement. Proc Natl Acad Sci U S A. 1970;65(3):528–35. Epub 1970/03/01. doi: 10.1073/pnas.65.3.528 4315612; PubMed Central PMCID: PMC282939.

24. Lachmann PJ, Davies A. Complement and immunity to viruses. Immunological reviews. 1997;159:69–77. Epub 1998/01/07. doi: 10.1111/j.1600-065x.1997.tb01007.x 9416503.

25. Da Costa XJ, Brockman MA, Alicot E, Ma M, Fischer MB, Zhou X, et al. Humoral response to herpes simplex virus is complement-dependent. Proc Natl Acad Sci U S A. 1999;96(22):12708–12. Epub 1999/10/27. doi: 10.1073/pnas.96.22.12708 10535987; PubMed Central PMCID: PMC23060.

26. Brockman MA, Knipe DM. Herpes simplex virus as a tool to define the role of complement in the immune response to peripheral infection. Vaccine. 2008;26 Suppl 8:I94–9. Epub 2009/04/24. doi: 10.1016/j.vaccine.2008.11.062 19388172; PubMed Central PMCID: PMC2742331.

27. Friedman HM. Immune evasion by herpes simplex virus type 1, strategies for virus survival. Trans Am Clin Climatol Assoc. 2003;114:103–12. Epub 2003/06/20. 12813914; PubMed Central PMCID: PMC2194497.

28. Nagashunmugam T, Lubinski J, Wang L, Goldstein LT, Weeks BS, Sundaresan P, et al. In vivo immune evasion mediated by the herpes simplex virus type 1 immunoglobulin G Fc receptor. J Virol. 1998;72(7):5351–9. Epub 1998/06/17. 9620988; PubMed Central PMCID: PMC110157.

29. McNearney TA, Odell C, Holers VM, Spear PG, Atkinson JP. Herpes simplex virus glycoproteins gC-1 and gC-2 bind to the third component of complement and provide protection against complement-mediated neutralization of viral infectivity. J Exp Med. 1987;166(5):1525–35. Epub 1987/11/01. doi: 10.1084/jem.166.5.1525 2824652; PubMed Central PMCID: PMC2189652.

30. Friedman HM, Wang L, Fishman NO, Lambris JD, Eisenberg RJ, Cohen GH, et al. Immune evasion properties of herpes simplex virus type 1 glycoprotein gC. J Virol. 1996;70(7):4253–60. Epub 1996/07/01. 8676446; PubMed Central PMCID: PMC190356.

31. Hung SL, Peng C, Kostavasili I, Friedman HM, Lambris JD, Eisenberg RJ, et al. The interaction of glycoprotein C of herpes simplex virus types 1 and 2 with the alternative complement pathway. Virology. 1994;203(2):299–312. Epub 1994/09/01. doi: 10.1006/viro.1994.1488 8053154.

32. Fries LF, Friedman HM, Cohen GH, Eisenberg RJ, Hammer CH, Frank MM. Glycoprotein C of herpes simplex virus 1 is an inhibitor of the complement cascade. J Immunol. 1986;137(5):1636–41. Epub 1986/09/01. 3018078.

33. Lubinski J, Nagashunmugam T, Friedman HM. Viral interference with antibody and complement. Semin Cell Dev Biol. 1998;9(3):329–37. Epub 1998/07/17. doi: 10.1006/scdb.1998.0242 9665870.

34. Hart ML, Saifuddin M, Spear GT. Glycosylation inhibitors and neuraminidase enhance human immunodeficiency virus type 1 binding and neutralization by mannose-binding lectin. J Gen Virol. 2003;84(Pt 2):353–60. Epub 2003/02/01. doi: 10.1099/vir.0.18734-0 12560567.

35. Thielens NM, Tacnet-Delorme P, Arlaud GJ. Interaction of C1q and mannan-binding lectin with viruses. Immunobiology. 2002;205(4–5):563–74. Epub 2002/10/25. doi: 10.1078/0171-2985-00155 12396016.

36. Matsushita M, Fujita T. Activation of the classical complement pathway by mannose-binding protein in association with a novel C1s-like serine protease. The Journal of experimental medicine. 1992;176(6):1497–502. Epub 1992/12/01. doi: 10.1084/jem.176.6.1497 1460414; PubMed Central PMCID: PMC2119445.

37. Matsushita M, Endo Y, Fujita T. Cutting edge: complement-activating complex of ficolin and mannose-binding lectin-associated serine protease. J Immunol. 2000;164(5):2281–4. Epub 2000/02/29. doi: 10.4049/jimmunol.164.5.2281 10679061.

38. Ma YJ, Skjoedt MO, Garred P. Collectin-11/MASP complex formation triggers activation of the lectin complement pathway—the fifth lectin pathway initiation complex. Journal of innate immunity. 2013;5(3):242–50. Epub 2012/12/12. doi: 10.1159/000345356 23220946.

39. Wakimoto H, Ikeda K, Abe T, Ichikawa T, Hochberg FH, Ezekowitz RA, et al. The complement response against an oncolytic virus is species-specific in its activation pathways. Mol Ther. 2002;5(3):275–82. Epub 2002/02/28. doi: 10.1006/mthe.2002.0547 11863417.

40. Thiel S, Vorup-Jensen T, Stover CM, Schwaeble W, Laursen SB, Poulsen K, et al. A second serine protease associated with mannan-binding lectin that activates complement. Nature. 1997;386(6624):506–10. Epub 1997/04/03. doi: 10.1038/386506a0 9087411.

41. Stengaard-Pedersen K, Thiel S, Gadjeva M, Moller-Kristensen M, Sorensen R, Jensen LT, et al. Inherited deficiency of mannan-binding lectin-associated serine protease 2. N Engl J Med. 2003;349(6):554–60. doi: 10.1056/NEJMoa022836 12904520.

42. Thiel S, Steffensen R, Christensen IJ, Ip WK, Lau YL, Reason IJ, et al. Deficiency of mannan-binding lectin associated serine protease-2 due to missense polymorphisms. Genes Immun. 2007;8(2):154–63. Epub 2007/01/26. doi: 10.1038/sj.gene.6364373 17252003.

43. Cedzynski M, Szemraj J, Swierzko AS, Bak-Romaniszyn L, Banasik M, Zeman K, et al. Mannan-binding lectin insufficiency in children with recurrent infections of the respiratory system. Clin Exp Immunol. 2004;136(2):304–11. Epub 2004/04/17. doi: 10.1111/j.1365-2249.2004.02453.x 15086395; PubMed Central PMCID: PMC1809017.

44. Garcia-Laorden MI, Garcia-Saavedra A, de Castro FR, Violan JS, Rajas O, Blanquer J, et al. Low clinical penetrance of mannose-binding lectin-associated serine protease 2 deficiency. J Allergy Clin Immunol. 2006;118(6):1383–6. Epub 2006/12/02. doi: 10.1016/j.jaci.2006.08.004 17137870.

45. Garcia-Laorden MI, Sole-Violan J, Rodriguez de Castro F, Aspa J, Briones ML, Garcia-Saavedra A, et al. Mannose-binding lectin and mannose-binding lectin-associated serine protease 2 in susceptibility, severity, and outcome of pneumonia in adults. J Allergy Clin Immunol. 2008;122(2):368–74, 74 e1-2. Epub 2008/06/28. doi: 10.1016/j.jaci.2008.05.037 18582923.

46. Olszowski T, Poziomkowska-Gesicka I, Jensenius JC, Adler G. Lectin pathway of complement activation in a Polish woman with MASP-2 deficiency. Immunobiology. 2014;219(4):261–2. Epub 2013/12/18. doi: 10.1016/j.imbio.2013.10.009 24332888.

47. Sokolowska A, Szala A, St Swierzko A, Kozinska M, Niemiec T, Blachnio M, et al. Mannan-binding lectin-associated serine protease-2 (MASP-2) deficiency in two patients with pulmonary tuberculosis and one healthy control. Cell Mol Immunol. 2015;12(1):119–21. Epub 2014/03/25. doi: 10.1038/cmi.2014.19 24658431; PubMed Central PMCID: PMC4654364.

48. Thiel S, Frederiksen PD, Jensenius JC. Clinical manifestations of mannan-binding lectin deficiency. Mol Immunol. 2006;43(1–2):86–96. doi: 10.1016/j.molimm.2005.06.018 16023210.

49. Inaba S, Okochi K, Yae Y, Niklasson F, de Verder CH. Serological studies of an SLE-associated antigen-antibody system discovered as a precipitation reaction in agarose gel: the HAKATA antigen-antibody system. Fukuoka Igaku Zasshi. 1990;81(9):284–91. Epub 1990/09/01. 2276712.

50. Atkinson AP, Cedzynski M, Szemraj J, St Swierzko A, Bak-Romaniszyn L, Banasik M, et al. L-ficolin in children with recurrent respiratory infections. Clin Exp Immunol. 2004;138(3):517–20. Epub 2004/11/17. doi: 10.1111/j.1365-2249.2004.02634.x 15544630; PubMed Central PMCID: PMC1809226.

51. Cedzynski M, Atkinson AP, St Swierzko A, MacDonald SL, Szala A, Zeman K, et al. L-ficolin (ficolin-2) insufficiency is associated with combined allergic and infectious respiratory disease in children. Mol Immunol. 2009;47(2–3):415–9. Epub 2009/09/22. doi: 10.1016/j.molimm.2009.08.028 19767106.

52. Genster N, Takahashi M, Sekine H, Endo Y, Garred P, Fujita T. Lessons learned from mice deficient in lectin complement pathway molecules. Molecular immunology. 2014;61(2):59–68. Epub 2014/07/26. doi: 10.1016/j.molimm.2014.07.007 25060538.

53. Avirutnan P, Hauhart RE, Marovich MA, Garred P, Atkinson JP, Diamond MS. Complement-mediated neutralization of dengue virus requires mannose-binding lectin. MBio. 2011;2(6). Epub 2011/12/15. doi: 10.1128/mBio.00276-11 22167226; PubMed Central PMCID: PMC3236064.

54. Singh SS, Cheung RC, Wong JH, Ng TB. Mannose Binding Lectin: A Potential Biomarker for Many Human Diseases. Curr Med Chem. 2016;23(33):3847–60. Epub 2016/08/20. doi: 10.2174/0929867323666160817162208 27538693.

55. Levi-Strauss M, Mallat M. Primary cultures of murine astrocytes produce C3 and factor B, two components of the alternative pathway of complement activation. J Immunol. 1987;139(7):2361–6. Epub 1987/10/01. 3655365.

56. Gasque P, Fontaine M, Morgan BP. Complement expression in human brain. Biosynthesis of terminal pathway components and regulators in human glial cells and cell lines. J Immunol. 1995;154(9):4726–33. Epub 1995/05/01. 7536777.

57. Morgan BP, Gasque P. Extrahepatic complement biosynthesis: where, when and why? Clin Exp Immunol. 1997;107(1):1–7. Epub 1997/01/01. doi: 10.1046/j.1365-2249.1997.d01-890.x 9010248; PubMed Central PMCID: PMC1904545.

58. Keizer MP, Kamp AM, Aarts C, Geisler J, Caron HN, van de Wetering MD, et al. The High Prevalence of Functional Complement Defects Induced by Chemotherapy. Frontiers in immunology. 2016;7:420. Epub 2016/11/02. doi: 10.3389/fimmu.2016.00420 27799929; PubMed Central PMCID: PMC5066094.

59. Drew JH, Arroyave CM. The complement system of the newborn infant. Biol Neonate. 1980;37(3–4):209–17. Epub 1980/01/01. doi: 10.1159/000241276 7362858.

60. Grumach AS, Ceccon ME, Rutz R, Fertig A, Kirschfink M. Complement profile in neonates of different gestational ages. Scand J Immunol. 2014;79(4):276–81. Epub 2014/01/28. doi: 10.1111/sji.12154 24460650.

61. Sergerie Y, Rivest S, Boivin G. Tumor necrosis factor-alpha and interleukin-1 beta play a critical role in the resistance against lethal herpes simplex virus encephalitis. J Infect Dis. 2007;196(6):853–60. Epub 2007/08/19. doi: 10.1086/520094 17703415.

62. Mancini M, Vidal SM. Insights into the pathogenesis of herpes simplex encephalitis from mouse models. Mammalian genome: official journal of the International Mammalian Genome Society. 2018;29(7–8):425–45. Epub 2018/09/01. doi: 10.1007/s00335-018-9772-5 30167845; PubMed Central PMCID: PMC6132704.

63. Mansur DS, Kroon EG, Nogueira ML, Arantes RM, Rodrigues SC, Akira S, et al. Lethal encephalitis in myeloid differentiation factor 88-deficient mice infected with herpes simplex virus 1. Am J Pathol. 2005;166(5):1419–26. Epub 2005/04/28. doi: 10.1016/S0002-9440(10)62359-0 15855642; PubMed Central PMCID: PMC1606396.

64. Perez de Diego R, Sancho-Shimizu V, Lorenzo L, Puel A, Plancoulaine S, Picard C, et al. Human TRAF3 adaptor molecule deficiency leads to impaired Toll-like receptor 3 response and susceptibility to herpes simplex encephalitis. Immunity. 2010;33(3):400–11. Epub 2010/09/14. doi: 10.1016/j.immuni.2010.08.014 20832341; PubMed Central PMCID: PMC2946444.

65. Andersen LL, Mork N, Reinert LS, Kofod-Olsen E, Narita R, Jorgensen SE, et al. Functional IRF3 deficiency in a patient with herpes simplex encephalitis. J Exp Med. 2015;212(9):1371–9. doi: 10.1084/jem.20142274 26216125; PubMed Central PMCID: PMC4548062.

66. Menasria R, Boivin N, Lebel M, Piret J, Gosselin J, Boivin G. Both TRIF and IPS-1 adaptor proteins contribute to the cerebral innate immune response against herpes simplex virus 1 infection. Journal of virology. 2013;87(13):7301–8. Epub 2013/04/19. doi: 10.1128/JVI.00591-13 23596298; PubMed Central PMCID: PMC3700287.

67. Wang JP, Bowen GN, Zhou S, Cerny A, Zacharia A, Knipe DM, et al. Role of specific innate immune responses in herpes simplex virus infection of the central nervous system. Journal of virology. 2012;86(4):2273–81. Epub 2011/12/16. doi: 10.1128/JVI.06010-11 22171256; PubMed Central PMCID: PMC3302371.

68. Abel L, Plancoulaine S, Jouanguy E, Zhang SY, Mahfoufi N, Nicolas N, et al. Age-dependent Mendelian predisposition to herpes simplex virus type 1 encephalitis in childhood. J Pediatr. 2010;157(4):623–9, 9 e1. Epub 2010/06/18. doi: 10.1016/j.jpeds.2010.04.020 20553844.

69. Sancho-Shimizu V, Perez de Diego R, Jouanguy E, Zhang SY, Casanova JL. Inborn errors of anti-viral interferon immunity in humans. Curr Opin Virol. 2011;1(6):487–96. Epub 2012/02/22. doi: 10.1016/j.coviro.2011.10.016 22347990; PubMed Central PMCID: PMC3280408.

70. Zhang SY, Boisson-Dupuis S, Chapgier A, Yang K, Bustamante J, Puel A, et al. Inborn errors of interferon (IFN)-mediated immunity in humans: insights into the respective roles of IFN-alpha/beta, IFN-gamma, and IFN-lambda in host defense. Immunological reviews. 2008;226:29–40. Epub 2009/01/24. doi: 10.1111/j.1600-065X.2008.00698.x 19161414.

71. Lima GK, Zolini GP, Mansur DS, Freire Lima BH, Wischhoff U, Astigarraga RG, et al. Toll-like receptor (TLR) 2 and TLR9 expressed in trigeminal ganglia are critical to viral control during herpes simplex virus 1 infection. The American journal of pathology. 2010;177(5):2433–45. Epub 2010/09/25. doi: 10.2353/ajpath.2010.100121 20864677; PubMed Central PMCID: PMC2966801.

72. McKenna A, Hanna M, Banks E, Sivachenko A, Cibulskis K, Kernytsky A, et al. The Genome Analysis Toolkit: a MapReduce framework for analyzing next-generation DNA sequencing data. Genome Res. 2010;20(9):1297–303. Epub 2010/07/21. doi: 10.1101/gr.107524.110 20644199; PubMed Central PMCID: PMC2928508.

73. Romanel A, Zhang T, Elemento O, Demichelis F. EthSEQ: ethnicity annotation from whole exome sequencing data. Bioinformatics. 2017;33(15):2402–4. Epub 2017/04/04. doi: 10.1093/bioinformatics/btx165 28369222; PubMed Central PMCID: PMC5818140.

74. Bjelkmar P, Larsson P, Cuendet MA, Hess B, Lindahl E. Implementation of the CHARMM Force Field in GROMACS: Analysis of Protein Stability Effects from Correction Maps, Virtual Interaction Sites, and Water Models. J Chem Theory Comput. 2010;6(2):459–66. Epub 2010/02/09. doi: 10.1021/ct900549r 26617301.

75. Hess B, Kutzner C, van der Spoel D, Lindahl E. GROMACS 4: Algorithms for Highly Efficient, Load-Balanced, and Scalable Molecular Simulation. J Chem Theory Comput. 2008;4(3):435–47. Epub 2008/03/01. doi: 10.1021/ct700301q 26620784.

76. MacKerell AD, Bashford D, Bellott M, Dunbrack RL, Evanseck JD, Field MJ, et al. All-atom empirical potential for molecular modeling and dynamics studies of proteins. J Phys Chem B. 1998;102(18):3586–616. Epub 1998/04/30. doi: 10.1021/jp973084f 24889800.

77. Dunbrack RL Jr. Rotamer libraries in the 21st century. Curr Opin Struct Biol. 2002;12(4):431–40. Epub 2002/08/07. doi: 10.1016/s0959-440x(02)00344-5 12163064.

78. Eswar N, Webb B, Marti-Renom MA, Madhusudhan MS, Eramian D, Shen MY, et al. Comparative protein structure modeling using Modeller. Curr Protoc Bioinformatics. 2006;Chapter 5:Unit-5 6. Epub 2008/04/23. doi: 10.1002/0471250953.bi0506s15 18428767; PubMed Central PMCID: PMC4186674.

79. Gal P, Harmat V, Kocsis A, Bian T, Barna L, Ambrus G, et al. A true autoactivating enzyme. Structural insight into mannose-binding lectin-associated serine protease-2 activations. J Biol Chem. 2005;280(39):33435–44. Epub 2005/07/26. doi: 10.1074/jbc.M506051200 16040602.

80. Pettersen EF, Goddard TD, Huang CC, Couch GS, Greenblatt DM, Meng EC, et al. UCSF Chimera—a visualization system for exploratory research and analysis. J Comput Chem. 2004;25(13):1605–12. Epub 2004/07/21. doi: 10.1002/jcc.20084 15264254.

81. Roger T, Schneider A, Weier M, Sweep FC, Le Roy D, Bernhagen J, et al. High expression levels of macrophage migration inhibitory factor sustain the innate immune responses of neonates. Proc Natl Acad Sci U S A. 2016;113(8):E997–1005. Epub 2016/02/10. doi: 10.1073/pnas.1514018113 26858459; PubMed Central PMCID: PMC4776487.

82. Boivin G, Goyette N, Sergerie Y, Keays S, Booth T. Longitudinal evaluation of herpes simplex virus DNA load during episodes of herpes labialis. J Clin Virol. 2006;37(4):248–51. Epub 2006/10/19. doi: 10.1016/j.jcv.2006.09.006 17046320.

Štítky
Hygiena a epidemiológia Infekčné lekárstvo Laboratórium

Článok vyšiel v časopise

PLOS Pathogens


2019 Číslo 12
Najčítanejšie tento týždeň
Najčítanejšie v tomto čísle
Kurzy

Zvýšte si kvalifikáciu online z pohodlia domova

Aktuální možnosti diagnostiky a léčby litiáz
nový kurz
Autori: MUDr. Tomáš Ürge, PhD.

Všetky kurzy
Prihlásenie
Zabudnuté heslo

Zadajte e-mailovú adresu, s ktorou ste vytvárali účet. Budú Vám na ňu zasielané informácie k nastaveniu nového hesla.

Prihlásenie

Nemáte účet?  Registrujte sa

#ADS_BOTTOM_SCRIPTS#