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Pediatria Polska - Polish Journal of Paediatrics
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Case report

Clinical manifestations, toxicities, and outcome of two children with Nijmegen breakage syndrome and lymphoid malignancies – case reports

Aleksandra Filipiuk
1
,
Agata Kozakiewicz
1
,
Kamil Kośmider
1
,
Katarzyna Karska
2
,
Monika Lejman
3
,
Joanna Zawitkowska
2

  1. Student Scientific Society, Department of Paediatric Haematology, Oncology, and Transplantology, Medical University of Lublin, Poland
  2. Department of Paediatric Haematology, Oncology, and Transplantology, Medical University of Lublin, Poland
  3. Laboratory of Genetic Diagnostics, Department of Paediatric Haematology, Oncology, and Transplantology, Medical University of Lublin, Poland
Pediatr Pol 2022; 97 (1): 48–52
Online publish date: 2022/03/23
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INTRODUCTION

Nijmegen breakage syndrome (NBS) is a rare autosomal recessive disorder of chromosomal instability that is more prevalent in Central and Eastern European populations. The NBN gene responsible for the entity is located on chromosome 8q21 and encodes the protein called nibrin. Most Slavic patients carry the founder mutation 657del5. This entity is clinically characterized by microcephaly, dysmorphic facial features, mild growth retardation, immunodeficiency, and a strong predisposition to develop malignancies (predominantly of lymphoid origin) [1]. A significant aberration in the peripheral T lymphocyte maturation process in patients with NBS in comparison with physiology was found in the latest studies. An increased number of senescent and exhausted T-cell populations (CD57, KLRG1, and PD1) might be related to increased suspicion of malignancy in patients with NBS [2].
We report 2 patients with NBS and T-cell lymphoblastic lymphoma (T-LBL) treated at the Department of Paediatric Haematology, Oncology, and Transplantology in Lublin in the years 2014-2020. Both patients were dia­gnosed with NBS by mutation analysis of the NBN gene, which revealed homozygosity for a typical 5 base pair deletion (657del5). The patients were treated according to EURO-LB 02 for the T-LBL protocol without reduction of cytotoxic drugs. Toxicity profiles during chemotherapy were classified according to the National Cancer Institute’s Common Toxicity Criteria. They received anti-infective prophylaxis including oral cotrimoxazole (25/5 mg/kg/day on 3 consecutive days per week) and oral fluconazole (10 mg/kg/day). The medical records of these children were reviewed for clinical and laboratory data and outcome.

CASE REPORTS

CASE 1

A 13-year-old boy with NBS was admitted to our hospital because of a palpable, painless right supraclavicular mass and fever for 7 days. The physical examination revealed bilateral clavicular and supraclavicular lymphadenopathy (4 × 2 cm on the right side and 2 × 2 cm on the left side), microcephaly, and dysmorphic facial features of NBS, such as a sloping forehead, large ears, and prominent nose. No comorbidities or significant findings in the patient’s family history were detected.
The patient was born at 37 + 1 weeks of gestation with a birth weight of 2800 g. His head circumference was 31 cm (< 3rd percentile). A genetic assessment was performed because of microcephaly and dysmorphic facial features. His mental development was normal for his age. The boy received intravenous immunoglobulins in the dose of 0.4 g/kg per month over 6 months during infancy. No severe infections were observed during childhood.
Laboratory parameters at admission are presented in Table 1. The ultrasound examination (US) of the neck showed lymph node conglomerates on both sides with reduced echogenicity and a rounded shape. Lymph node biopsy was performed for histopathological examination, and the child was diagnosed with T-LBL. Mediastinal involvement was confirmed using magnetic resonance imaging (MRI) – bilateral conglomerates of lymph nodes sized 68 × 28 × 25 mm on the right side and 67 × 20 × 19 mm on the left side. Pathological nodal masses descended and surrounded the superior vena cava, aortic arch, and trachea. Abdominal US, bone marrow biopsy, and cerebrospinal fluid examination were all normal.
The child was classified as stage III and started on treatment in July 2014, according to the EURO-LB 02 protocol (Table 2). The patient achieved complete remission on the 33rd day of induction. Phase Ia was complicated by anaemia, febrile neutropaenia, oral mucositis grade 3, and peripheral neurotoxicity grade 2. The delay in the next course of chemotherapy in our patient was 7 days, due to an upper respiratory tract infection. After the first administration of high-dose methotrexate (HDMTX) a grade 3 epileptic seizure was observed, which responded to dia­zepam (0.1 mg/kg body weight). Subsequent infusions of HDMTX were well tolerated. No severe complications were observed during re-induction or maintenance. Currently, in the 4-year follow-up, the child is alive and well.

CASE 2

A 3-year-old boy was admitted to our hospital because of submandibular lymphadenopathy with fever for 7 days and a 2-month history of pain in the lower limbs. The patient was treated with amoxicillin with no improvement for 3 days. The physical examination on admission revealed bilateral clavicular and submandibular lymphadenopathy (5 × 4 cm), enlargement of the inguinal lymph nodes, and splenomegaly. Microcephaly and dysmorphic facial features, such as a sloping forehead and prominent nose, were observed. No comorbidities or significant findings in the patient’s family history were detected.
The patient was born abroad at 36 + 6 weeks of gestation with a birth weight of 2530 g. The boy was microcephalic, with his head circumference at one month being 33 cm (< 3rd percentile). Medical investigations made in the United Kingdom did not include NBS. Computed tomography revealed no structural brain lesions. His mental development was normal for his age. He experienced recurrent upper respiratory tract infections when he attended kindergarten. The diagnosis of NBS was established after the manifestation of lymphoma at the Department of Paediatric Haematology and Oncology and Transplantology in Lublin by sequencing exon 6 of the NBN gene, which revealed homozygosity for a typical 5 base pair deletion. The karyotype of peripheral blood lymphocytes also revealed chromosomal instability involving chromosome 7.
The laboratory parameters at admission are presented in Table 1. The child was diagnosed with T-LBL on histopathological examination. Chest MRI revealed lymph nodes in the area of mandibular angles – 10 × 13 mm on the right side and 8 × 11 mm on the left side. On both sides of the supraclavicular pits, several lymph nodes sized up to 6 mm in the short axes were observed. In the area of the anterior mediastinum, bilateral conglomerates of lymph nodes sized 78 × 32 × 31 mm on the right side and 78 × 18 × 24 mm on the left side were found. Pathological nodal masses descended to the mediastinum, surrounding the superior vena cava, aortic arch, and trachea. The nodal masses were strengthened after the administration of a paramagnetic contrast agent. Abdominal US demonstrated lymphadenopathy and conglomerates 44 × 22 mm in size in the abdomen. Small pericardial effusion (pericardial thickness 3 mm) was observed on echocardiography. The evaluation of cerebrospinal fluid excluded central nervous system involvement. Bone marrow aspirate showed the presence of 6% lymphoblasts.
He was classified as stage IV and started on treatment in August 2019, according to the EURO-LB 02 protocol (Table 2). The boy received intravenous immunoglobulins in the dose of 0.4 g/kg body weight per month during all courses of chemotherapy. On the 15th day of induction, MRI and US revealed decreased neck, breast, and abdominal masses, and parietal remission was achieved. Phase Ia was complicated by peripheral neurotoxicity grade 3 (according to the National Cancer Institute’s Common Toxi­city Criteria). The delay of the next Ib induction phase in our patient was 7 days. During this phase of therapy (on day 58) hepatotoxicity grade 2 occurred (alanine transaminase 138 IU/l, aspartate transaminase 58 IU/l). Chemotherapy was delayed by 9 days. After consolidation (phase M), progression of the disease was reported with bone marrow and mediastinal relapse. The boy was qualified for haematopoietic stem cell transplantation due to progression of the disease. The treatment was changed, and second-line therapy was implemented. The detailed therapy schedule is presented in Table 3. The boy received chemotherapy according to IntReALL HR 2010 protocol. He received an HIB course with the proteasome inhibitor bortezomib and achieved partial regression. This phase was complicated by a grade 3 seizure episode. During the next HC1 course, disease progression in the neck and mediastinum was observed. Subsequent treatment consisting of a combination of bortezomib and cytotoxic agents was implemented. However, we still observed progression of the disease, and the patient subsequently died.

DISCUSSION

The analysis shows the highest prevalence of NBS in Poland (3.1/1,000,000) and in the Czech Republic (3.1/1,000,000) [3-5]. Overall, Sharapova et al. estimated the highest prevalence of NBS cases in the Vistula watershed as the geographical hot spot of NBS [5]. Microce­phaly at birth has been described as the leading symptom of NBS [1]. Therefore, the significance of a detailed diagnostic approach to microcephaly in childhood is important for identifying patients with NBS, to optimize medical support and cancer prevention. Recording the patient’s medical and family history and a clinical examination are the first step in the diagnosis. Subsequently, cranial MRI or cerebral US with genetic assessment should be performed. Routine metabolic screening of patients with primary microcephaly is not required [6].
Many children are still diagnosed with NBS after cancer presentation. The median age at diagnosis of NBS is appro­ximately 5 years, and 27% of patients have been dia­gnosed with malignancies [7]. In Case 1, a genetic diagnosis of NBS was made after birth. In Case 2, the NBS was genetically confirmed during the disclosure of lymphoma when the boy was 3 years old. Earlier investigations due to microcephaly and dysmorphic facial phenotype did not include NBS. Sharapova et al. described malignancy in 62 (45.6%) patients with NBS. The median age at cancer presentation was 9.31 years [5]. In our first case, lymphoma was diagnosed when the patient was 13 years old. The cumu­lative cancer incidence was approximately 40.21% and 77.78% at 10 and 20 years of follow-up, respectively [7].
A holistic preventive approach is essential for children with NBS. The first signs of lymphoma are often misdia­gnosed by paediatricians because of their similarity to immunodeficiency-related diseases. Lymphoid malignancies should be considered in the differential diagnoses. Research has been carried out to identify the parameters that would enable patient prognosis. Cooperation between an oncologist, a geneticist and a clinical immunologist seems to be significant in the preventive approach for children with NBS. Wolska-Kuśnierz et al. emphasized the importance of monitoring the levels of immunoglobulins due to their correlation with the severity of respiratory tract infections and cancer predisposition. Statistical analysis showed a significant impact of the degree of IgG, IgG1, IgG4, and/or IgA deficiency [3]. In Case 1, we reported normal immunological parameters during the diagnosis of lymphoma. The patient received immunoglobulin therapy during childhood. The levels of immunoglobulins including serum IgA and IgG, IgG1, and IgG2 were decreased in Case 2. The patient received regular IVIG therapy during chemotherapy. NBS patients with latent Epstein-Barr virus (EBV) infection should be carefully monitored. The median viral load is higher in patients with lymphoma [8]. In the second case, elevated levels of anti-EBV viral capsid antigen IgG antibodies were observed.
Characteristic cellular features of NBS include spontaneous chromosomal aberrations, usually affecting T-cell receptor gene cluster and immunoglobulin heavy chain gene cluster [9]. In Case 2, chromosomal instability involving chromosome 7 was described by karyotype analysis. Additionally, telomere attrition also mediates chromosomal instability, which may explain the high incidence of lymphomas in patients with NBS [10].
Hypersensitivity to ionizing radiation triggers changes during initial staging of lymphoma in patients with NBS. MRI or US should be used instead of computed tomography or X-ray [1]. In Case 1 and Case 2, the diagnosis was made using MRI and US.
There are no specific protocols for the treatment of lymphoid malignancies in children with NBS. The decision to reduce cytostatic agents depends on the oncologist and is based on the detailed medical history of every patient. In the literature, cases of successful treatment of lymphomas with reduced doses of cytotoxic agents have been described [11]. In Russian’s cohort studies, conventional unmodified regimens were well tolerated in 65% of patients with malignancy [12]. Our Case 1 and Case 2 patients received chemotherapy courses at the scheduled dose without any modification according to the EURO LB-02.
It is well known that therapy-related side effects are more common among patients with immunodeficiencies. Wolska-Kusnierz et al. reported that infectious complications (85%) were the most frequent cause of treatment-related toxicity [7]. Similarly, Zawitkowska et al. observed 44% of microbiologically documented infections in immunocompromised children [13]. In contrast, Landmann et al. reported 65 severe adverse effects in 51 patients with lymphoblastic lymphomas without immunodeficiencies. The most frequent toxicities were haematological toxicity, coagulation problems, infection, and liver toxicity [14]. In our patients, we observed 4 grade 3 adverse events – oral mucositis and 3 episodes of epileptic seizures. Moreover, fatal infectious complications, especially of fungal aetio­logy, are visibly more common in NBS patients (16%) compared with immunocompromised patients (2%) [3].
The outcome of these patients is extremely poor. Complete remission is achieved in less than 40% of patients, which is visibly less than in the general paediatric population. The 5-year overall survival rate in NBS patients is 25% and the median survival is 3.8 years, compared to immunocompromised patients, in whom it is 82% and 10.3 years, respectively. [3]. Most children with T-LBL die due to disease relapse. The second patient died due to progression of the disease. There is a great impact of haematopoietic stem cell transplantation on the long-term survival of patients with NBS and malignancies, including T-LBL. Patients who received haematopoietic stem cell transplantation had a significantly higher 20-year overall survival rate (42.7%) in comparison with the patients who did not (30.3%). The median follow-up time of patients with NBS and malignancies is 13 years [7].

CONCLUSIONS

Our reports highlight that a standardized approach is essential for the immediate identification of frequent causes of microcephaly. Patients with NBS and lymphoid malignancies are particularly vulnerable to high incidence progression of disease and therapy-associated toxicity.

DISCLOSURE

The authors declare no conflict of interest.

REFERENCES

1. Chrzanowska KH, Gregorek H, Dembowska-Bagińska B, et al. Nij­megen breakage syndrome (NBS). Orphanet J Rare Dis 2012; 7: 13.
2. Piatosa B, Wolska-Kuśnierz B, Tkaczyk K, et al. T lymphocytes in patients with Nijmegen breakage syndrome demonstrate features of exhaustion and senescence in flow cytometric evaluation of matu­ration pathway. Front Immunol 2020; 11: 1319.
3. Wolska-Kuśnierz B, Gregorek H, Chrzanowska K, et al. Nijmegen breakage syndrome: clinical and immunological features, long-term outcome and treatment options − a retrospective analysis. J Clin Immunol 2015; 35: 538-549.
4. Seemanova E, Varon R, Vejvalka J, et al. The Slavic NBN founder mutation: a role for reproductive fitness? PLoS One 2016; 11: e0167984.
5. Sharapova SO, Pashchenko OE, Bondarenko AV, et al. Geographical distribution, incidence, malignancies, and outcome of 136 Eastern Slavic patients with Nijmegen breakage syndrome and NBN founder variant c.657_661del5. Front Immunol 2021; 11: 602482.
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9. Włodarczyk M, Lejman M. Chromosomal instability associated with adverse outcome: a case report of patient with Nijmegen breakage syndrome and rapidly developed T-NHL with complex karyotype. Mol Cytogenet 2020; 13: 35.
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11. Pastorczak A, Szczepanski T, Mlynarski W; International Berlin- Frankfurt-Munster (I-BFM) ALL host genetic variation working group. Clinical course and therapeutic implications for lymphoid malignancies in Nijmegen breakage syndrome. Eur J Med Genet 2016; 59: 126-132.
12. Deripapa E, Balashov D, Rodina Y, et al. Prospective study of a cohort of Russian nijmegen breakage syndrome patients demonstrating predictive value of low kappa-deleting recombination excision circle (KREC) numbers and beneficial effect of hematopoietic stem cell transplantation (HSCT). Front Immunol 2017; 8: 807.
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14. Landmann E, Burkhardt B, Zimmermann M, et al. Results and conclusions of the European Intergroup EURO-LB02 trial in children and adolescents with lymphoblastic lymphoma. Haematologica 2017; 102: 2086-2096.
Copyright: © 2022 Polish Society of Paediatrics. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
 
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