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Observation |

X-Linked Ectodermal Dysplasia With Immunodeficiency Caused by NEMO Mutation:  Early Recognition and Diagnosis FREE

Anthony J. Mancini, MD; Leslie P. Lawley, MD; Gulbu Uzel, MD
[+] Author Affiliations

Author Affiliations: Division of Dermatology, Children's Memorial Hospital and Departments of Pediatrics and Dermatology, Northwestern University Feinberg School of Medicine, Chicago, Illinois (Drs Mancini and Lawley); and Laboratory of Clinical Infectious Diseases, National Institutes of Health, National Institute of Allergy and Infectious Diseases, Bethesda, Maryland (Dr Uzel).


Arch Dermatol. 2008;144(3):342-346. doi:10.1001/archderm.144.3.342.
Text Size: A A A
Published online

Background  X-linked ectodermal dysplasia with immunodeficiency (XL-EDA-ID) is described in patients with hypomorphic mutations in IKBKG (the inhibitory κB kinase γ gene), which encodes nuclear factor κB essential modulator (NEMO). Features include hypohidrosis, dental anomalies, alopecia, and immunodeficiency. Boys with NEMO mutations often present with serious infections, but the NEMO mutations are rarely diagnosed early in infancy. Cutaneous features in these patients are poorly elucidated.

Observations  A 12-week-old male infant presented with a recalcitrant skin eruption, intertrigo, atopiclike dermatitis, and erythroderma. Alopecia, frontal bossing, and periorbital wrinkling were present, and family history revealed incontinentia pigmenti in his mother. Laboratory evaluation revealed leukocytosis with eosinophilia, low IgG and IgM levels, and absent IgA. Flow cytometry revealed lymphocytosis with elevated CD3+ and CD4+ counts and low levels of natural killer cells. Amplification and sequencing of IKBKG revealed insertion of cytosine at nucleotide 1167 (1167-1168insC) in exon 10, with frameshift mutation in the zinc-finger domain. Peripheral blood stem cell transplantation led to initial engraftment and improvement in his skin findings, but his engrafted cell counts diminished, and a second stem cell transplantation was planned.

Conclusions  Mutations in NEMO should be considered in male infants with recalcitrant seborrheic or atopic dermatitislike eruptions and intertrigo, especially when features of ectodermal dysplasia are present. Early recognition and diagnosis are desirable, prior to the onset of manifestations of immunodeficiency.

Figures in this Article

Ectodermal dysplasia (ED) refers to a group of inherited disorders involving absence or dysplasia of the ectodermal appendages. Clinically, it is characterized by absence, abnormality, or deficient function of ectodermal derivatives, including skin, teeth, hair, eccrine glands, or nails. The hypohidrotic/anhidrotic form of ED (HED/EDA) has been attributed to at least 4 genes (EDA1 [ectodysplasin]; EDA3; EDAR [the EDA-A1 isoform receptor]; and EDARADD [EDAR-associated death domain]), with at least 3 modes of inheritance1: X-linked recessive (OMIM 305100), autosomal dominant (OMIM 129490), and autosomal recessive (OMIM 224900). Recently, the syndrome of X-linked EDA with immunodeficiency (XL-EDA-ID) (OMIM 300291) was described in patients with hypomorphic mutations in IKBKG (inhibitory κB kinase γ gene), which encodes NEMO (nuclear factor κB [NF-κB] essential modulator), the regulatory subunit of the IKK (IκB kinase) complex. The NEMO complex is essential for NF-κB signaling,2 and NF-κB is a heterogeneous collection of cytoplasmic dimers that, once free of its regulatory subunit, enters the nucleus to initiate transcription of a variety of genes involved in immunity, inflammation, apoptosis, adhesion, and cell growth.3

Mutations of NEMO are difficult to diagnose early in infancy for male patients, most presenting with manifestations of immunodeficiency.4 Herein, we describe a male infant with XL-EDA-ID caused by NEMO mutation diagnosed at age 12 weeks and subsequently treated with allogeneic stem cell transplantation.

PATIENT MEDICAL HISTORY

A 12-week-old male infant presented to the pediatric dermatology clinic for a persistent skin eruption since age 1 month. He was born after a 39-week uncomplicated pregnancy, delivered via elective cesarean section to a 40-year-old gravida 2, para 2 woman. Examination revealed a well-developed male infant with the following growth parameters: weight at the 10th to 25th percentile for age, length at the 10th to 25th percentile for age, and head circumference at the 50th percentile for age. His scalp revealed diffuse alopecia and diffuse, yellow, greasy scales superimposed on erythema (Figure 1). He was noted to have mild frontal bossing, periorbital wrinkling, and an everted lower lip (Figure 2). His axillary and inguinal folds and perianal region revealed erosive erythema (Figure 3), and his umbilicus was erythematous and moist. His oral mucosa was clear, and he had no lymphadenopathy or hepatosplenomegaly.

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Figure 1.

Diffuse alopecia, erythema, and scaling of the scalp.

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Figure 2.

Frontal bossing, periorbital wrinkling, and a thickened, everted lower lip.

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Figure 3.

Inguinal and perianal erythema with erosions.

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He was initially diagnosed with severe intertrigo and seborrheic dermatitis and treated with oxiconazole nitrate, 1%, and alclometasone diproprionate, 0.05%, creams, oral cephalexin, and oral fluconazole. A prior culture had revealed heavy growth of Staphylococcus aureus that was pansensitive. Findings from fungal and repeated bacterial cultures from affected skin fold areas were negative. Given the severity of involvement, a laboratory evaluation for immunodeficiency was performed.

Subsequently, his mother reported having been diagnosed with incontinentia pigmenti as a child, with apparent mild expressivity. She recalled her history of blisters with eventual spontaneous involution. She denied any history of dental or musculoskeletal defects, ophthalmic abnormalities (aside from myopia), and developmental abnormalities or seizures. Her hair and nails were normal, and findings of her most recent skin examination were notable only for faintly hyperpigmented linear and whorled streaks following the lines of Blaschko on the posterior aspects of her legs and flanks.

Throughout his early course, the patient's skin involvement varied. He developed intermittent erythroderma with patchy clearing (Figure 4), yet the intertrigo was a fairly persistent finding. He had occasional atopic dermatitislike, erythematous, scaly plaques superimposed on a background of faint erythroderma. During his pretransplantation hospitalization and conditioning, he developed increasing erythroderma with crusted fissures of the abdomen and lateral aspects of the legs. Skin culture yielded methicillin-resistant S aureus, and he was treated with intravenous vancomycin with clearance. Also during the pretransplantation course, he displayed poor weight gain, diarrhea, and vomiting with feeding. Gastrointestinal evaluation and endoscopy were performed, revealing normal-appearing mucosa. Biopsy specimens of the duodenum and sigmoid colon showed nonspecific findings without viral inclusion bodies or granulomas. Of note, he had no radiologic evidence of osteopetrosis and no lymphedema of the limbs.

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Figure 4.

Erythroderma with patches of sparing. The patient also had persistent intertrigo.

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LABORATORY FINDINGS

Complete blood cell count revealed leukocytes at 22 710/μL (normal range, 5000/μL-19 500/μL) and platelets at 597 000/μL (normal range, 150 000/μL-450 000/μL). Hemoglobin level was 11.3 g/dL (normal range, 9.0-14.0 g/dL). The differential analysis revealed 6% monocytes (normal range, 3%-10%), 55.8% lymphocytes (normal range, 44%-74%), 30.4% neutrophils (normal range, 14%-34%), 6.4% eosinophils (normal range, 0%-6%), and 1.4% basophils (normal range, 0%-2%). The results of chemical analysis were normal. Findings of a chronic granulomatous disease flow study were normal, as were the expression of CD11b integrin (ruling out leukocyte adhesion deficiency) and mitogen stimulation assays (phytohemagglutinin, concanavalin A, and pokeweed mitogen). Tetanus titer showed undetectable levels, and a quantitative assay for immunoglobulins revealed a normal level of IgE, no detectable IgA, and diminished levels of IgG (128 mg/dL; normal range, 169-558 mg/dL) and IgM (11.5 mg/dL; normal range, 23-85 mg/dL).

Flow cytometry revealed overall lymphocytosis (lymphocyte count, 12 672/μL; normal range, 3886/μL-10 750/μL) with significantly increased numbers of CD3+ and CD4+ T lymphocytes (7476/μL; normal range, 1392/μL-5210/μL) expressing activation markers and increased numbers of double-negative T lymphocytes (CD3+ CD4 CD8) but very few natural killer cells (CD3 CD16+ CD56+). His T-cell receptor Vβ repertoire suggested polyclonal T cells, which made maternal transplacental T-cell engraftment unlikely. Review of peripheral blood smear findings revealed no features suggestive of hematologic malignancy. The recombination activating genes RAG1 and RAG2 as well as interleukin 7 (IL-7) receptor sequences revealed no mutations, ruling out Omenn syndrome and a severe combined immunodeficiency (SCID) with maternally engrafted cells.

To convert leukocytes and lymphocytes to number of cells × 109/L, multiply by 0.001; platelets to number of platelets × 103/μL, multiply by 1.0; hemoglobin to grams per liter, multiply by 10.0; and IgA and IgM to milligrams per liter, multiply by 10.0.

Sequencing of the coding region of IKBKG revealed insertion of cytosine at nucleotide 1167 (1167-1168insC) in exon 10, resulting in a predicted frameshift at codon 390 (E390fsX394), and a short protein without the zinc-finger domain. Molecular testing of his mother revealed heterozygosity for the same mutation. Both sisters were tested and found to be homozygous for the wild-type gene.

HISTOPATHOLOGIC FINDINGS

Skin biopsy was performed during a follow-up visit at age 4 months (prior to confirmation of the NEMO mutation) to assess for possible graft-vs-host disease (GVHD). Hematoxylin-eosin staining revealed acanthosis and spongiosis of the epidermis and a superficial interface and perivascular lymphohistiocytic infiltrate with focal satellite cell necrosis (Figure 5). Numerous necrotic keratinocytes were noted as were pigment-laden macrophages. The changes were considered to be consistent with GVHD with a superimposed eczematous process. Interestingly, the findings from his variable number of tandem repeats (VNTR) studies for maternal engraftment in both peripheral blood and skin biopsy specimens were reported as negative, ruling out the possibility of GVHD.

Place holder to copy figure label and caption
Figure 5.

Histologic features of skin biopsy specimens taken at age 4 months. A, The epidermis shows slight acanthosis and spongiosis with a superficial interface and perivascular lymphohistiocytic infiltrate and focal satellite cell necrosis (hematoxylin-eosin, original magnification ×10). B, Necrotic keratinocytes are visible in the epidermis and pigment-laden macrophages in the upper dermis (hematoxylin-eosin, original magnification ×20).

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THERAPY

The patient was initially treated with intravenous immunoglobulin, trimethoprim-sulfamethoxazole (Pneumocystis prophylaxis), azithromycin (mycobacterial prophylaxis), cyclosporine A, and prednisone. He subsequently had peripheral blood stem cell transplantation with donor cells from his HLA-matched sister. Chimerism studies revealed initial engraftment, and 1 month after transplantation, some initial improvement in his skin was noted. Subsequently, he developed vomiting and diarrhea, and repeated endoscopy with bowel biopsies revealed acute GVHD. His clinical course was also complicated by pseudotumor cerebri, which was believed to be medication induced and eventually resolved.

Three months after transplantation, his skin was improved with only mild erythema and xerosis, and his alopecia resolved with growth of scalp, eyelash, and eyebrow hair. Subsequently, results of his VNTR studies continued to reveal diminished numbers of engrafted myeloid cells, and a second stem cell transplantation (using a modified reduced-intensity conditioning protocol for nonmalignant disorders5) was recommended.

Defects in the NF-κB pathway have been linked to several human diseases, including incontinentia pigmenti, ED, EDA-ID, osteopetrosis and/or lymphedema with EDA and ID (OL-EDA-ID), familial cylindromatosis, von Hippel-Lindau disease, primary lymphedema, a variety of osteoclast diseases, inflammatory bowel disease, Blau syndrome, familial cold autoinflammatory syndrome, and Muckle-Wells syndrome.6 Nuclear factor κB dimers are involved in the development and function of the immune system, with activation affecting a diverse array of immunity- and inflammation-associated genes, including acute-phase reactants, cytokines, chemokines, growth factors and receptors, adhesion molecules, and regulators of apoptosis and cellular proliferation.7 Nuclear factor κB also plays an essential role in ectoderm development through its association with (and activation through) the EDAR/ectodysplasin A pathway.8 Nuclear factor κB essential modulator, or NEMO, has been the topic of frequent scientific and clinical interest in recent years. Large- scale deletions of IKBKG, the gene encoding NEMO, result in incontinentia pigmenti, an X-linked dominant genodermatosis. Around 80% of new mutations are caused by deletions in exons 4 to 10, with truncation and loss of protein function.9,10 The effects of this mutation lead to death for most affected male fetuses, while female fetuses survive because of the moderating effects of skewed X-inactivation, with selective elimination of cells expressing the mutation.11

Hypomorphic mutations in IKBKG, which result in some preservation of NEMO function, are well described as a cause of XL-EDA-ID. The exact incidence of XL-EDA-ID caused by NEMO mutation is unknown, and clinical features vary in severity based on the residual function of the mutated protein. Hypohidrosis, delayed tooth eruption, coarse hair, and immunodeficiency with frequent bacterial infections may be present.12 Hair may be absent (atrichosis) or minimally present (hypotrichosis), and hypohidrosis may result in heat intolerance or heat stroke. Other dental findings include hypodontia or anodontia with conical incisors and gapped teeth. An autosomal dominant form of EDA-ID has been described, associated with a gain-of-function mutation of IκBα (an inhibitor of the IKK complex), thereby impairing NF-κB activation.13 This form is distinguished by a severe T-cell immunodeficiency. Immunodeficiency without EDA has also been recognized with IKBKG mutations, suggesting that different mutations in this gene may result in distinct clinical and immunologic phenotypes.14,15 While mutations in the coding region of IKBKG are associated with EDA-ID, stop codon mutations cause a more severe syndrome with associated osteopetrosis and lymphedema (OL-EDA-ID).1,7 Hence, hypomorphic mutations in this gene cause 2 allelic conditions.1

The type of immunodeficiency seen in patients with XL-EDA-ID varies. The most consistent finding is impairment of antibody response to polysaccharides.12,16,17 Other reported defects include defective natural killer cell activity, impairments in CD40-mediated B-cell activation and isotype class switching, impaired response to lipopolysaccharide stimulation, and decreased production of tumor necrosis factor and IL-12.3,4,12,1820 Patients with XL-EDA-ID are predisposed to infections with pyogenic bacteria during early infancy, including Streptococcus pneumoniae, because they are unable to mount a specific antibody response against the polysaccharide antigens.2,21 Other common pathogens include Haemophilus influenzae, S aureus, Klebsiella, Salmonella, and Pseudomonas species, as well as mycobacteria (including Mycobacterium avium intracellulare), cytomegalovirus, herpes simplex virus and Pneumocystis carinii.2,3,15,22 Infections may present as sepsis, pneumonia, otitis media, sinusitis, lymphadenitis, bronchiectasis (secondary to recurrent pyogenic pulmonary infections), skin and soft tissue infections, and infections of the bones and gastrointestinal tract.3,22

The skin abnormalities in patients with XL-EDA-ID (aside from the classic features associated with ED) largely lack mention in the existing literature. Dry, pale, wrinkled, and/or hyperpigmented skin are all noted. In 1 cohort, prominence of superficial veins was present in 3 of 7 affected siblings.23 A chronic, atopiclike dermatitis with prominent involvement of the neck and intertriginous areas has been described.4

Our patient presented with extensive and recalcitrant intertrigo and seborrheic dermatitis, with progression to erythroderma, a cutaneous phenotype reminiscent of that described in patients with other congenital immunodeficiencies such as severe combined immunodeficiency and Omenn syndrome. The possibility of cutaneous GVHD was considered before his immune defect was known, and while the skin biopsy findings were consistent, the demonstrated lack of maternal engraftment did not support this diagnosis. Other potential explanations include a GVHD-like clinical presentation from autoreactive T lymphocytes or a GVHD-like histologic mimic resulting from keratinocyte apoptosis related to the NEMO mutation. Our patient's facial appearance evolved over time, with a gradually increasing prominence of periorbital wrinkling, inferior periorbital duskiness, flattening of the malar ridges, a thick everted lower lip, and frontal bossing, all consistent with the facial features noted in HED/EDA.

The mutation noted in our patient (1167-1168insC) has been described in several patients.18,21 A trend noted in several of these patients includes decreased serum levels of IgA (noted in our patient) and elevation of IgM levels. Infectious complications varied, but bacterial sepsis was common, and 3 of the reported patients with this mutation developed disseminated mycobacterial (M avium intracellulare) infection. In 1 series of 7 patients with NEMO mutation and ID, the 2 with this mutation were noted to have the most severe clinical courses.18 Clarification of genotype-phenotype correlations is desirable and will likely evolve with further observations and reports of patients with XL-EDA-ID.

The optimal therapy and prognosis for patients with XL-EDA-ID are unclear. Ectodermal dysplasia is managed supportively, with the goals of minimizing overheating and preventing long-term preventable sequelae such as impaired speech development and cosmetic disfigurement. Early dental intervention with use of dental prostheses and/or implants is indicated, and referral to the National Foundation for Ectodermal Dysplasias (www.nfed.org) is important for patients and families. Treatment for the immunodeficiency may include immune-based therapies (such as intravenous immunoglobulin) and aggressive management of infections, including prophylaxis against (and/or treatment for) gram-positive and gram-negative bacteria, mycobacteria, cytomegalovirus, herpes simplex virus, and P carinii.14,18,19 Hematopoietic stem cell transplantation offers the potential advantage of immune reconstitution but bears the risks of obligatory immunosuppression, including disseminated infection (especially mycobacterial) and organ toxic effects.19,24 Following peripheral blood stem cell transplantation, our patient showed improvement in his skin appearance and evidence of initial engraftment from his sister's donor cells, but eventually the good effect waned. Because of the immunologic dysregulation and infectious risks associated with NEMO mutations, a second stem cell transplantation is planned.

In summary, we describe a patient with XL-EDA-ID due to a hypomorphic mutation in NEMO diagnosed at age 5 months. Subsequent to his diagnosis, the patient's mother recalled her prior diagnosis of incontinentia pigmenti (with very mild expressivity), and molecular testing revealed her heterozygosity for the same mutation. The NEMO mutation should be considered in male infants presenting with extensive or recalcitrant seborrheic or atopic dermatitislike skin eruptions and intertrigo, especially when facial features of ED or maternal history of incontinentia pigmenti are present.

Correspondence: Anthony J. Mancini, MD, Division of Dermatology, Children's Memorial Hospital, 2300 Children's Plaza No. 107, Chicago, IL 60614 (amancini@northwestern.edu).

Accepted for Publication: April 6, 2007.

Author Contributions: Dr Mancini had full access to all of the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: Mancini. Acquisition of data: Mancini and Lawley. Analysis and interpretation of data: Mancini and Uzel. Drafting of the manuscript: Mancini. Critical revision of the manuscript for important intellectual content: Mancini, Lawley, and Uzel. Administrative, technical, and material support: Mancini. Study supervision: Mancini and Uzel.

Financial Disclosure: Dr Mancini has served as a paid consultant and/or received honoraria from Astellas, Novartis, Connetics, Galderma, and Ranbaxy.

Additional Contributions: Ronald Berne, MD, initially referred the patient.

Smahi  ACourtois  GRabia  SH  et al.  The NF-kappaB signaling pathway in human diseases: from incontinentia pigmenti to ectodermal dysplasias and immune-deficiency syndromes. Hum Mol Genet 2002;11 (20) 2371- 2375
PubMed
Döffinger  RSmahi  ABessia  C  et al.  X-linked anhidrotic ectodermal dysplasia with immunodeficiency is caused by impaired NF-kappaB signaling. Nat Genet 2001;27 (3) 277- 285
PubMed
Uzel  G The range of defects associated with nuclear factor kappaB essential modulator. Curr Opin Allergy Clin Immunol 2005;5 (6) 513- 518
PubMed
Schmid  JMJunge  SAHossle  JP  et al.  Transient hemophagocytosis with deficient cellular cytotoxicity, monoclonal immunoglobulin M gammopathy, increased T-cell numbers, and hypomorphic NEMO mutation. Pediatrics 2006;117 (5) e1049- e1056
PubMed
Shenoy  SGrossman  WJDiPersio  J  et al.  A novel reduced-intensity stem cell transplant regimen for nonmalignant disorders. Bone Marrow Transplant 2005;35 (4) 345- 352
PubMed
Orange  JSLevy  OGeha  RS Human disease resulting from gene mutations that interfere with appropriate nuclear factor-kappaB activation. Immunol Rev 2005;20321- 37
PubMed
Puel  APicard  CKu  CLSmahi  ACasanova  JL Inherited disorders of NF-kappaB-mediated immunity in man. Curr Opin Immunol 2004;16 (1) 34- 41
PubMed
Orange  JSGeha  RS Finding NEMO: genetic disorders of NF-[kappa]B activation. J Clin Invest 2003;112 (7) 983- 985
PubMed
Steffann  JRaclin  VSmahi  A  et al.  A novel PCR approach for prenatal detection of the common NEMO rearrangement in incontinentia pigmenti. Prenat Diagn 2004;24 (5) 384- 388
PubMed
Pauly  ELinderkamp  OPoschl  J Incontinentia pigmenti in combination with decreased IgG subclass concentrations in a female newborn. Biol Neonate 2005;88 (3) 172- 174
PubMed
Mansour  SWoffendin  HMitton  S  et al.  Incontinentia pigmenti in a surviving male is accompanied by hypohidrotic ectodermal dysplasia and recurrent infection. Am J Med Genet 2001;99 (2) 172- 177
PubMed
Nishikomori  RAkutagawa  HMaruyama  K  et al.  X-linked ectodermal dysplasia and immunodeficiency caused by reversion mosaicism of NEMO reveals a critical role for NEMO in human T-cell development and/or survival. Blood 2004;103 (12) 4565- 4572
PubMed
Courtois  GSmahi  AReichenbach  J  et al.  A hypermorphic IkappaBalpha mutation is associated with autosomal dominant anhidrotic ectodermal dysplasia and T cell immunodeficiency. J Clin Invest 2003;112 (7) 1108- 1115
PubMed
Niehues  TReichenbach  JNeubert  J  et al.  Nuclear factor kappaB essential modulator-deficient child with immunodeficiency yet without anhidrotic ectodermal dysplasia. J Allergy Clin Immunol 2004;114 (6) 1456- 1462
PubMed
Orange  JSLevy  OBrodeur  SR  et al.  Human nuclear factor kappa B essential modulator mutation can result in immunodeficiency without ectodermal dysplasia. J Allergy Clin Immunol 2004;114 (3) 650- 656
PubMed
Ku  CLDupuis-Girod  SDittrich  AM  et al.  NEMO mutations in 2 unrelated boys with severe infections and conical teeth. Pediatrics 2005;115 (5) e615- e619
PubMed
Schweizer  PKalhoff  HHorneff  GWahn  VDiekmann  L Polysaccharide specific humoral immunodeficiency in ectodermal dysplasia: case report of a boy with two affected brothers. Klin Padiatr 1999;211 (6) 459- 461
PubMed
Orange  JSJain  ABallas  ZKSchneider  LCGeha  RSBonilla  FA The presentation and natural history of immunodeficiency caused by nuclear factor kappaB essential modulator mutation. J Allergy Clin Immunol 2004;113 (4) 725- 733
PubMed
Orange  JSBrodeur  SRJain  A  et al.  Deficient natural killer cell cytotoxicity in patients with IKK-gamma/NEMO mutations. J Clin Invest 2002;109 (11) 1501- 1509
PubMed
Jain  AMa  CALiu  SBrown  MCohen  JStrober  W Specific missense mutations in NEMO result in hyper-IgM syndrome with hypohydrotic ectodermal dysplasia. Nat Immunol 2001;2 (3) 223- 228
PubMed
Zonana  JElder  MESchneider  LC  et al.  A novel X-linked disorder of immune deficiency and hypohidrotic ectodermal dysplasia is allelic to incontinentia pigmenti and due to mutations in IKK-gamma (NEMO). Am J Hum Genet 2000;67 (6) 1555- 1562
PubMed
Carrol  EDGennery  ARFlood  TJSpickett  GPAbinun  M Anhidrotic ectodermal dysplasia and immunodeficiency: the role of NEMO. Arch Dis Child 2003;88 (4) 340- 341
PubMed
Ørstavik  KHKristiansen  MKnudsen  GP  et al.  Novel splicing mutation in the NEMO (IKK-gamma) gene with severe immunodeficiency and heterogeneity of X-chromosome inactivation. Am J Med Genet A 2006;140 (1) 31- 39
PubMed
Dupuis-Girod  SCorradini  NHadj-Rabia  S  et al.  Osteopetrosis, lymphedema, anhidrotic ectodermal dysplasia, and immunodeficiency in a boy and incontinentia pigmenti in his mother. Pediatrics 2002;109 (6) e97
PubMed

Figures

Place holder to copy figure label and caption
Figure 1.

Diffuse alopecia, erythema, and scaling of the scalp.

Graphic Jump Location
Place holder to copy figure label and caption
Figure 2.

Frontal bossing, periorbital wrinkling, and a thickened, everted lower lip.

Graphic Jump Location
Place holder to copy figure label and caption
Figure 3.

Inguinal and perianal erythema with erosions.

Graphic Jump Location
Place holder to copy figure label and caption
Figure 4.

Erythroderma with patches of sparing. The patient also had persistent intertrigo.

Graphic Jump Location
Place holder to copy figure label and caption
Figure 5.

Histologic features of skin biopsy specimens taken at age 4 months. A, The epidermis shows slight acanthosis and spongiosis with a superficial interface and perivascular lymphohistiocytic infiltrate and focal satellite cell necrosis (hematoxylin-eosin, original magnification ×10). B, Necrotic keratinocytes are visible in the epidermis and pigment-laden macrophages in the upper dermis (hematoxylin-eosin, original magnification ×20).

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Tables

References

Smahi  ACourtois  GRabia  SH  et al.  The NF-kappaB signaling pathway in human diseases: from incontinentia pigmenti to ectodermal dysplasias and immune-deficiency syndromes. Hum Mol Genet 2002;11 (20) 2371- 2375
PubMed
Döffinger  RSmahi  ABessia  C  et al.  X-linked anhidrotic ectodermal dysplasia with immunodeficiency is caused by impaired NF-kappaB signaling. Nat Genet 2001;27 (3) 277- 285
PubMed
Uzel  G The range of defects associated with nuclear factor kappaB essential modulator. Curr Opin Allergy Clin Immunol 2005;5 (6) 513- 518
PubMed
Schmid  JMJunge  SAHossle  JP  et al.  Transient hemophagocytosis with deficient cellular cytotoxicity, monoclonal immunoglobulin M gammopathy, increased T-cell numbers, and hypomorphic NEMO mutation. Pediatrics 2006;117 (5) e1049- e1056
PubMed
Shenoy  SGrossman  WJDiPersio  J  et al.  A novel reduced-intensity stem cell transplant regimen for nonmalignant disorders. Bone Marrow Transplant 2005;35 (4) 345- 352
PubMed
Orange  JSLevy  OGeha  RS Human disease resulting from gene mutations that interfere with appropriate nuclear factor-kappaB activation. Immunol Rev 2005;20321- 37
PubMed
Puel  APicard  CKu  CLSmahi  ACasanova  JL Inherited disorders of NF-kappaB-mediated immunity in man. Curr Opin Immunol 2004;16 (1) 34- 41
PubMed
Orange  JSGeha  RS Finding NEMO: genetic disorders of NF-[kappa]B activation. J Clin Invest 2003;112 (7) 983- 985
PubMed
Steffann  JRaclin  VSmahi  A  et al.  A novel PCR approach for prenatal detection of the common NEMO rearrangement in incontinentia pigmenti. Prenat Diagn 2004;24 (5) 384- 388
PubMed
Pauly  ELinderkamp  OPoschl  J Incontinentia pigmenti in combination with decreased IgG subclass concentrations in a female newborn. Biol Neonate 2005;88 (3) 172- 174
PubMed
Mansour  SWoffendin  HMitton  S  et al.  Incontinentia pigmenti in a surviving male is accompanied by hypohidrotic ectodermal dysplasia and recurrent infection. Am J Med Genet 2001;99 (2) 172- 177
PubMed
Nishikomori  RAkutagawa  HMaruyama  K  et al.  X-linked ectodermal dysplasia and immunodeficiency caused by reversion mosaicism of NEMO reveals a critical role for NEMO in human T-cell development and/or survival. Blood 2004;103 (12) 4565- 4572
PubMed
Courtois  GSmahi  AReichenbach  J  et al.  A hypermorphic IkappaBalpha mutation is associated with autosomal dominant anhidrotic ectodermal dysplasia and T cell immunodeficiency. J Clin Invest 2003;112 (7) 1108- 1115
PubMed
Niehues  TReichenbach  JNeubert  J  et al.  Nuclear factor kappaB essential modulator-deficient child with immunodeficiency yet without anhidrotic ectodermal dysplasia. J Allergy Clin Immunol 2004;114 (6) 1456- 1462
PubMed
Orange  JSLevy  OBrodeur  SR  et al.  Human nuclear factor kappa B essential modulator mutation can result in immunodeficiency without ectodermal dysplasia. J Allergy Clin Immunol 2004;114 (3) 650- 656
PubMed
Ku  CLDupuis-Girod  SDittrich  AM  et al.  NEMO mutations in 2 unrelated boys with severe infections and conical teeth. Pediatrics 2005;115 (5) e615- e619
PubMed
Schweizer  PKalhoff  HHorneff  GWahn  VDiekmann  L Polysaccharide specific humoral immunodeficiency in ectodermal dysplasia: case report of a boy with two affected brothers. Klin Padiatr 1999;211 (6) 459- 461
PubMed
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