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May 2021; 8 (3) ArticleOpen Access

Hemophagocytic Lymphohistiocytosis Gene Mutations in Adult Patients Presenting With CLIPPERS-Like Syndrome

Guillaume Taieb, Elsa Kaphan, Claire Duflos, Christine Lebrun-Frénay, Valérie Rigau, Eric Thouvenot, Emeline Duhin-Gand, Romain Lefaucheur, Khe Hoang-Xuan, Sarah Coulette, Jean Christophe Ouallet, Nicolas Menjot de Champfleur, Christine Tranchant, Capucine Picard, Mathieu Fusaro, Fernando E. Sepulveda, Pierre Labauge, Geneviève de Saint Basile
First published March 3, 2021, DOI: https://doi.org/10.1212/NXI.0000000000000970
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Abstract

Objective To determine whether adult cases of Chronic Lymphocytic Inflammation with Pontine Perivascular Enhancement Responsive to Steroids (CLIPPERS) may be related to familial hemophagocytic lymphohistiocytosis (HLH) causes, we have screened patients with adult-onset CLIPPERS for mutations in primary HLH-associated genes.

Methods In our cohort of 36 patients fulfilling the criteria for probable or definite CLIPPERS according to the CLIPPERS-2017 criteria, we conducted a first study on 12 patients who consented to genetic testing. In these 12 patients, systemic HLH criteria were searched, and genetic analysis of 8 genes involved in primary HLH was performed.

Results Four definite and 8 probable CLIPPERS were enrolled (n = 12). Mutations involved in HLH were identified in 2 definite and 2 probable CLIPPERS (4/12). Three of them had biallelic PRF1 mutations with reduced perforin expression in natural killer cells. The remaining patient had biallelic UNC13D mutations with cytotoxic lymphocyte impaired degranulation. None of the mutated patients reached the criteria for systemic HLH. During follow-up, 3 of them displayed atypical findings for CLIPPERS, including emergence of systemic non-Hodgkin lymphoma (1/3) and confluent gadolinium-enhancing lesions on brain MRI (3/3).

Conclusions In our patients presenting with adult-onset CLIPPERS, one-third have HLH gene mutations. This genetic treatable condition should be searched in patients with CLIPPERS, especially in those presenting with atypical findings.

Glossary

CLIPPERS=
Chronic Lymphocytic Inflammation with Pontine Perivascular Enhancement Responsive to Steroids;
HLH=
hemophagocytic lymphohistiocytosis;
HSCT=
hematopoietic stem cell transplantation;
IQR=
interquartile range;
NK=
natural killer

In 2010, Pittock et al. described 8 patients presenting with symptomatic hindbrain punctate and curvilinear gadolinium-enhancing lesions, responsive but dependent to steroids. These lesions were related to perivascular lymphohistiocytic infiltrates on brainstem biopsies.1 The authors named this CNS inflammatory disorder CLIPPERS for Chronic Lymphocytic Inflammation with Pontine Perivascular Enhancement Responsive to Steroids. Since this first description, more than 80 cases have been reported around the world.2,,5 The mean age at onset was about 50 years (range 13–86 years) with a slight male preponderance. Diagnostic criteria have been proposed in 2017.6 In the absence of specific biomarker, these criteria are based on clinical (i.e., subacute brainstem signs and symptoms responsive to steroids), radiologic (i.e., hindbrain punctate and curvilinear gadolinium-enhancing lesions responsive to steroids), and histologic features (i.e., perivascular and parenchymal CNS infiltrates composed by T cells and macrophages), with lack of alternative diagnosis (e.g., primary angiitis of the CNS, autoimmune gliopathies [related to antimyelin oligodendrocyte glycoprotein or antiglial fibrillary acidic protein antibodies], and CNS lymphoma).7 Patients were considered as definite CLIPPERS when all criteria are met and probable CLIPPERS in the absence of histologic confirmation. Recently, mutations in genes associated with familial hemophagocytic lymphohistiocytosis (HLH) have been found in 4 children presenting with isolated CNS involvement sharing some CLIPPERS features.8 We anticipated that HLH restricted to the CNS could be an interesting candidate to explain some CLIPPERS characteristics such as the presence of numerous histiocytes in the perivascular infiltrates and the striking association with lymphomas. Therefore, we screened adult patients with CLIPPERS for mutations in HLH-associated genes.

Methods

Standard Protocol Approvals, Registrations, and Patient Consents

The study protocol was approved by the local investigational review boards and the French Advisory Committee on Medical Research (IRB registration no. 00001072, no. CPP: 2015-03-03/DC 2014-2272). Written informed consent for genetic testing was obtained from each patient analyzed.

Study Population

Since 2011, University Hospitals of Montpellier collected clinical, radiologic, and histologic data of patients referred as CLIPPERS and displaying hindbrain punctate and/or curvilinear gadolinium enhancements. Thirty-six patients aged 18 years or older met the criteria for probable or definite CLIPPERS according to the CLIPPERS-2017 criteria.6 All patients had clinical and radiologic assessments, ancillary tests, and in some of them brain biopsies. The procedure of these investigations was previously described and is summarized in table e-1 (links.lww.com/NXI/A421).7

We conducted a first study on 12 patients who consented to genetic testing for familial HLH. Clinical and biological signs of HLH according to the HLH criteria were assessed in each patient at the time of genetic testing (table e-1, links.lww.com/NXI/A421).9 The presence of hemophagocytosis on histologic sections of brain tissue samples was searched at the time of the biopsy in case 2 and retrospectively in the 3 remaining biopsied patients (cases 3, 11, and 12). Finally, clinical and radiologic CLIPPERS features, ancillary tests, and the presence of systemic signs of HLH were reassessed at each new relapse from the time of genetic sampling and until January 2020 corresponding to the end of follow-up. Clinical and radiologic atypical features for CLIPPERS are summarized in table e-1.

Molecular and Functional Analyses

Eight genes involved in primary HLH were screened: PRF1, UNC13D, STX11, and STXBP2 associated with familial early-onset HLH, RAB27A and LYST associated with Griscelli syndrome and Chediak-Higashi syndrome, respectively, and SAP and XIAP associated with X-linked lymphoproliferative syndrome.10,11 Genetic screening was performed on DNA isolated from peripheral blood samples using a next-generation sequencing panel that simultaneously analyzed the 8 genes. Identified mutations were confirmed by Sanger sequencing.

An additional blood sample allowed assessing the percentage of circulating activated cytotoxic T lymphocytes (i.e., CD8+HLA-DR+ T cells that are frequently increase in primary HLH), the serum level of soluble interleukin-2 receptor alpha (CD25), the perforin expression level, and the cytotoxic lymphocyte degranulation ability as previously described.12 Perforin expression was assessed on natural killer (NK) cells by flow cytometry, and the level of expression was expressed as the mean fluorescent intensity of each patient sample relative to the control one. Perforin expression and cytotoxic lymphocyte degranulation activity of a mutated patient were compared each time to the one of a healthy control analyzed in the same conditions.

Statistical Analysis

The quantitative data are presented as median (interquartile range [IQR]), and the qualitative data are presented as number and frequencies or percentages. Median follow-up from the start of the disease to the end of follow-up was calculated for each patient. At the end of follow-up, to assess whether there was a difference between mutated and nonmutated patients with CLIPPERS, all data collected were compared between these 2 groups of patients. Tests were Fisher exact tests for qualitative variables and Student t tests for quantitative variables, unless for Rankin scale (Wilcoxon-Mann-Whitney). p Values <0.05 were considered statistically significant.

Data Availability

Anonymized data used for this study are available from the corresponding author on reasonable request to any qualified investigator.

Results

Demographic Characteristics and Initial Assessment of Patients

In this first study, genetic assessment was performed in 12 patients (9 males and 3 females) among 36 patients diagnosed as CLIPPERS (table 1). Five of them have already been reported elsewhere, including 1 patient shown here to carry HLH gene mutations.4,7,13 According to the CLIPPERS-2017 criteria, 8 patients met the clinical and radiologic CLIPPERS criteria and were considered as probable CLIPPERS, and 4 patients met the clinical, radiologic, and histologic criteria and were considered as definite CLIPPERS. The median age at onset was 56 (IQR 45–66.5) years. Patients were followed during a median of 38.5 months (IQR 27.5–87.5 months), and the median number of attacks per patient was 2 (IQR 2–3).

View this table:
Table 1

Characteristics of Patients With CLIPPERS

Description and Follow-up of Mutated Patients With CLIPPERS

Biallelic variations in genes involved in primary HLH were identified in 2 definite and 2 probable CLIPPERS (cases 1–4) (table 2). These 4 patients with nonconsanguineous parents were Caucasians. Three of them carried PRF1 variations (compound heterozygous in 2 [cases 3 and 4] and homozygous in 1 [case 1]), previously reported to partially impair lymphocyte cytotoxicity.14,,16 Hence, a reduced perforin expression was observed in the patients' NK cells (figure 2). The fourth patient (case 2) carried compound heterozygous variations in UNC13D, i.e., a nonsense mutation and a missense mutation predicted to be likely pathogenic (table 2 and figure 2). As a result, patient's cytotoxic T lymphocyte degranulation was partially impaired (figure 2). Two patients (cases 1 and 2) had a slight increased in the percentage of circulating activated CD8 T cells (22% and 16% respectively, normal ≤10 of CD8 HLA-DR+; table 2) supporting a T lymphocyte–driven disease as observed in primary HLH.17 None of the mutated patients had history of recurrent infections or severe viral infection. After a median follow-up of 42 months (IQR 31–81.5 months), 3 of them displayed atypical findings for CLIPPERS, shifting the initial diagnosis from CLIPPERS to non-CLIPPERS. The median time interval to the development of atypical features was 16 months (minimum 13, maximum 24). Case 2 developed a systemic B-cell non-Hodgkin lymphoma requiring a polychemotherapy (table 1). In cases 1 to 3, brain MRI showed confluent gadolinium-enhancing lesions on postcontrast T1-weighted images with large T2 hyperintensities on corresponding areas (figure 1). Brain biopsies targeting these atypical enhancing lesions in cases 2 and 3 showed characteristic perivascular lymphohistiocytic infiltrates seen in CLIPPERS with a predominance of CD4 T cells. There were neither unusual pathologic features nor signs of hemophagocytosis. As usually described in CLIPPERS, no patient relapsed when prednisone was above 30 mg per day. The median modified Rankin Scale score at the last visit was 2 (IQR 2–3.5). These mutated patients did not reach the criteria for systemic HLH (table 2). Except systemic lymphoma in case 2, no triggering factor for HLH was found in the 3 remaining mutated patients. Regarding familial background of case 3, his brother's granddaughter displayed a self-limited acute cerebellitis of unknown origin, and genetic screening showed a monoallelic mutation in PRF1.

View this table:
Table 2

HLH Evaluation in the Patients Carrying Mutation in Primary HLH-Related Genes

Figure 1
Figure 1 Radiologic Features of Mutated Patients With CLIPPERS

MRI at the first evaluation showed in all patients typical pontine punctate and curvilinear gadolinium enhancements on postcontrast T1WI (A, D, G, and J). In patients 1 to 3, MRI at the second attack displayed atypical confluent gadolinium-enhancing lesions on postcontrast T1WI (B, E, and H) with large T2/FLAIR hyperintensities on corresponding areas (C, F, and I). In patient 4, MRI at the second and third attacks still showed typical punctate gadolinium enhancements on postcontrast T1WI (K) with punctate T2/FLAIR hyperintensities on corresponding areas (L). CLIPPERS = Chronic Lymphocytic Inflammation with Pontine Perivascular Enhancement Responsive to Steroids; FLAIR = fluid-attenuated inversion recovery.

Figure 2
Figure 2 Patient Mutations and Their Consequences on Protein Expression or Function

(A) Sanger sequencing chromatogram depicting the homozygous (in P1) and heterozygous (in P2-4) mutations identified in PRF1 and UNC13D genes; (B) Flow cytometric analysis of perforin expression at the surface of natural killer cells from P1, P3, and P4. Histograms show overlays of unstained (gray) and perforin stained natural killer cells (black) from each patient (doted line) and a control (solid line) performed in the same experiment. (C) Degranulation of cytotoxic T lymphoblasts from patient P2 (gray curve) compared with control (black curve). Induced CD107 surface expression on cytotoxic T lymphoblasts activated by increased concentration of anti-CD3 (OKT3) is partially impaired in P2.

Description and Follow-up of Nonmutated Patients With CLIPPERS

In patients with CLIPPERS without identified mutation in the primary HLH genes analyzed (cases 5–12), 2 were definite CLIPPERS and 6 were probable CLIPPERS (table 1). After a median follow-up of 36 months (IQR 27–87.5), atypical clinical, radiologic, and/or histologic findings for CLIPPERS were not seen. In case 5, a nodular spinal cord enhancing lesion at the cervical level was seen during the first attack. This lesion disappeared under steroid therapy and did not relapse during the 2 further attacks (118 months of follow-up). As usually described in CLIPPERS, no patient relapsed when prednisone was above 30 mg per day. The median modified Rankin Scale score at the last visit was 1 (IQR 0.5–2.5). None of the nonmutated patients reached the criteria for systemic HLH. Except HIV type 1 in case 12, no triggering factor for HLH was found. These patients had no significant familial background of CNS disorder or history of hemophagocytosis.

Comparison Between Mutated and Nonmutated Patients With CLIPPERS

Data including age at onset, number of attacks, duration of follow-up, modified Rankin Scale score, presence of pontine gadolinium-enhancing lesions spreading (i.e., brain and/or spinal cord), CSF analysis, presence of systemic signs of HLH, and presence of clinical, radiologic, and/or histologic atypical features for CLIPPERS at the last follow-up were compared between mutated and nonmutated patients with CLIPPERS (table 3). Only the presence of atypical features for CLIPPERS was significantly more frequent in mutated patients (p = 0.02).

View this table:
Table 3

Comparison Between Mutated and Nonmutated Patients With CLIPPERS

Discussion

Primary HLH gene mutations were found in 33% of our patients presenting with adult-onset CLIPPERS. The mutated patients herein reported had no familial history of HLH or chronic CNS disorder. In addition, none of them met the criteria for the diagnosis of systemic HLH, although all exhibited a deficit in a protein involved in lymphocyte cytotoxicity. The reason for the CNS-restricted manifestations in these patients is not fully understood. It has been well recognized that systemic HLH manifestations due to a functional defect in T lymphocytes and NK cells cytotoxicity, result from impaired antigen clearance.10,18 Antigen persistence leads to lymphocyte and macrophage overactivation, systemic inflammatory cytokine release, and multiorgan failure. In the context of systemic HLH, about half of the patients have CNS involvement.19 However, because the diagnosis of HLH requires systemic signs, the prevalence of CNS-restricted involvement with underlying HLH pathophysiology is not determined.

It is noticeable that the perforin mutations identified in our patients are all hypomorphic gene variants preserving some protein function. Through different combinations, these mutations have been previously associated with late or atypical forms of HLH or to malignancies.14,,16 Degranulation activity of cytotoxic cells is also partially preserved in the patient carrying UNC13D mutations. In these situations, the residual lymphocyte cytotoxicity may be sufficient to prevent acute systemic HLH development in response to most environmental triggers, but not in response to specific triggers localized in some organs, particularly in the CNS. We cannot exclude in our patients the existence of specific neuroinflammatory events and/or the contribution of additional modifying factors that favored the onset of CNS-restricted HLH in this deficient cytotoxicity context.

Of interest, three-fourth of the mutated patients subsequently developed atypical radiologic features for CLIPPERS including confluent gadolinium-enhancing lesions with large T2 hyperintensities. In one of them, a systemic B-cell non-Hodgkin lymphoma appeared 21 months after disease onset. In this patient, the impaired lymphocyte cytotoxicity may have contributed to the emergence of B-cell lymphoma.15 In our study, the emergence of atypical CLIPPERS findings was only seen in the mutated patients. However, one of the mutated patients still met the CLIPPERS criteria despite 2 relapses and 43 months of follow-up. Emergence of atypical features for CLIPPERS may therefore represent a discriminating sign although not absolute given it absence in 1 patient harboring mutations in familial HLH-associated genes. Atypical features may also take longer to appear in some cases. Thus, screening for mutations in genes related to primary HLH should be fostered in all patients presenting with CLIPPERS.

Determination of such genetic alterations in patients with CLIPPERS is significant because hematopoietic stem cell transplantation (HSCT) is currently the only curative treatment for primary HLH. Besides, new specific therapies targeting cellular or soluble immune effectors of HLH are increasingly available, that may be worth to consider.20 Recently, 4 children presenting with chronic CNS inflammatory disorders associated with mutations in familial HLH genes achieved sustained remission after unrelated donor HSCT.8 Of interest, one of them met the CLIPPERS criteria and subsequently developed confluent gadolinium-enhancing lesions with large T2 hyperintensities before the graft. Although the place of HSCT remains to be defined, this therapy should be considered in patients with CLIPPERS features harboring mutations in primary HLH genes, who become resistant to steroids and immunosuppressive therapies.21 The present study raises another issue: whether CLIPPERS is a disease or a syndrome.22,,24 Our data strongly support the idea that CLIPPERS is a heterogeneous condition, potentially with different pathways of pathogenesis, resulting in similar clinical presentation. No mutations in the primary HLH genes were detected in 67% of our patients with CLIPPERS. We cannot totally exclude that some of them carried undetectable mutations in these genes. Alternatively, they may have mutations in other uncharacterized genes and/or have been exposed to environmental factors triggering HLH features in CNS. Following this line, CLIPPERS could reflect either a primary or a secondary form of CNS-restricted HLH. Among our nonmutated patients, 1 had HIV. This virus is known to potentially trigger secondary HLH.25 Other possible triggers associated with CLIPPERS were also described as triggers of HLH such as Epstein-Barr virus, systemic lymphomas, and more recently histiocytic sarcoma.26,,28

Given the small number of patients genetically tested in our cohort, additional studies are needed to better evaluate the prevalence of mutations in genes related to primary HLH in the patients presenting with CLIPPERS. In addition, because signs of HLH were not systematically searched in the untested patients of our cohort, we cannot totally rule out a selection bias.

Nevertheless, we thought that primary HLH should be searched in patients with CLIPPERS, especially in those presenting with atypical findings. Further studies may help to better delineate the different causes and mechanisms leading to CLIPPERS features in patients with primary HLH.

Study Funding

This work was supported by INSERM and the association LHF Espoir.

Disclosure

The authors report no disclosures relevant to the manuscript. Go to Neurology.org/NN for full disclosures.

Acknowledgment

Benjamin Taieb helped design the figures. The authors are grateful to Frederic Guerin, Nathalie Lambert, Virginie Grandin, and Corinne Jacques for their technical assistance.

Appendix Authors

Table

Footnotes

  • Go to Neurology.org/NN for full disclosures. Funding information is provided at the end of the article.

  • The Article Processing Charge was funded by CHU of Montpellier.

  • Received September 29, 2020.
  • Accepted in final form January 5, 2021.

This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND), which permits downloading and sharing the work provided it is properly cited. The work cannot be changed in any way or used commercially without permission from the journal.

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