Kostmann syndrome is a group of diseases that affect myelopoiesis, causing a congenital form of neutropenia (severe congenital neutropenia [SCN]), usually without other physical malformations. SCN manifests in infancy with life-threatening bacterial infections.^[1]

Most cases of SCN responds to treatment with granulocyte colony-stimulating factor (filgrastim), which increases the neutrophil count and decreases the severity and frequency of infections.^[1] Although this treatment has significantly improved survival, people with SCN are at risk of long-term complications such as hematopoietic clonal disorders (myelodysplastic syndrome, acute myeloid leukemia).

Kostmann disease (SCN3), the initial subtype recognized, was clinically described in 1956. This type has an autosomal recessive inheritance pattern, whereas the most common subtype of Kostmann syndrome, SCN1, shows autosomal dominant inheritance.

Usage

Kostmann disease is a form of severe congenital neutropenia (SCN), specifically type 3 (SCN3),^[2] which is a rare autosomal recessive condition in which severe chronic neutropenia is detected soon after birth.^[3][4] The disorder was discovered in 1956 in an extended family in northern Sweden by Rolf Kostmann, a Swedish doctor.^[5][6]

Severe congenital neutropenia (SCN) is used as the overarching term for all diseases that affect myelopoiesis most prominently. Kostmann syndrome can restrictively refer to Kostmann disease specifically, or can be used synonymously with SCN as an umbrella term. These syndrome subtypes are phenotypically similar despite arising from different gene abnormalities.^[7]

Although mutations of more than 15 genes cause severe congenital neutropenia (in a general sense)^[8] not all of these are usually considered as SCN. Clinical usage excludes two broad categories of congenital neutropenia. Diseases are excluded that overtly affect multiple systems rather than impacting myelopoiesis most prominently. Thus SCN excludes the severe neutropenia which can occur in congenital diseases such as Shwachman-Diamond syndrome, Barth syndrome, Chediak-Higashi syndrome, WHIM syndrome, and glycogen storage disease type Ib.^[8] A further group of other miscellaneous inherited disorders, such as hyper-IgM syndrome, Hermansky–Pudlak syndrome (HPS), Griscelli syndrome (GS), PN, P14 deficiency, Cohen syndrome, Charcot–Marie–Tooth disease (CMT) can show congenital neutropenia, but lack bone marrow findings typical of SCN.

This group of diseases may also have additional features such as partial albinism, retinopathy, or neuropathy, and are not inclined to degenerate into acute myelogenous leukemia.^[7]

Presentation

Infants with SCN have frequent infections: 50% have a significant infection within 1 month, most others by 6 months.^[7] Their etiology is usually bacterial, especially staphylococcal, and they commonly involve abscesses, both cutaneous and of internal organs, pneumonia, mastoiditis (inflammation of the mastoid process), and sepsis. All of these are life-threatening for infants. ^[9]

Genetics

Kostmann disease, SCN3, is inherited in an autosomal recessive manner, but the commonest subtype of Kostmann syndrome, SCN1, is autosomal dominant.^[3]

A significant proportion of SCN lacks a known mutation.^[12] The recognized subtypes of Kostmann syndrome are:

• SCN1 is the commonest form of SCN, which accounts for 60-80% of SCN,^[7] and the first to be genetically typified.^[7] This autosomal dominant form that arises from mutations of the ELANE (formerly ELA2) gene on chromosome 19p13.3, which encodes neutrophil elastase.^[10] Over a hundred ELANE mutations have been found in SCN1.^[13] This same gene is mutated in cyclic neutropenia.^[13]
• SCN2 is caused by heterozygous (autosomal dominant) mutation of the GFI1 gene on chromosome 1p22.^[14] GFI1 is a repressor of several transcriptional processes, including ELANE,^[7][14] as well as miR-21 and miR-196b micro-RNAs which influence myelopoiesis.^[7]
• SCN3 is the "classical", autosomal recessive form of Kostmann disease which arises from homozygous mutations in the HAX1 gene on chromosome 1p22.1. About one third of SCN3 individuals also have neurological changes including seizures, learning disabilities, or developmental delay.^[7]
• SCN4 is caused by autosomal recessive mutation of the G6PC3 gene on 17q21.^[15] SCN4 is associated with structural cardiac abnormalities, enlarged liver, intermittent thrombocytopenia and a prominent superficial venous pattern.^[15] A subset of SCN4 has severe primary pulmonary hypertension and respiratory failure.^[15]
• SCN5 arises from autosomal recessive Thr224Asn mutation in the VPS45 gene on chromosome 1q21.2.^[16] Unlike classical Kostmann disease, SCN5 also has defective platelet aggregation (thrombasthenia) and myelofibrosis.^[17] This type is refractory to granulocyte colony-stimulating factor. There is an absence of lysosomes in fibroblasts and depletion of alpha granules in platelets. Accelerated apoptosis occurs in the neutrophils and bone marrow.
• X-linked SCN (SCNX) is caused by mutation in the WASP gene on Xp11.^[18]

SCN occasionally may arise from SBDS mutations.^[12]

Diagnosis

An absolute neutrophil count (ANC) chronically less than 500/mm3, usually less than 200/mm3, is the main sign of Kostmann's. Other elements include the severity of neutropenia, the chronology (from birth; not emerging later), and other normal findings (hemoglobin, platelets, general body health). Isolated neutropenia in infants can occur in viral infections, autoimmune neutropenia of infancy, bone marrow suppression from a drug or toxin, hypersplenism, and passive placental transfer of maternal IgG.^[7]

A bone marrow test can assist in diagnosis. The bone marrow usually shows early granulocyte precursors, but myelopoietic development stops ("arrests") at the promyelocyte and/or myelocyte stage, so that few maturing forms are seen. Neutrophil survival is normal.

Needs mention of (rarer) myelokathexis types. e.g. G6PC3 variant and

Pathophysiology

The various mutations may be responsible for the untimely initiation of apoptosis in myelocytes, producing their premature destruction. There may be, in addition, other underlying molecular/genetic changes producing DNA mutations and genome instability, which contribute to initiation and progression of this disease.

MDS/AML

Therapy

Regular administration of exogenous granulocyte colony-stimulating factor (filgrastim) clinically improves neutrophil counts and immune function and is the mainstay of therapy, although this may increase risk for myelofibrosis and acute myeloid leukemia in the long term.^[19]

Over 90% of SCN responds to treatment with granulocyte colony-stimulating factor (filgrastim), which has significantly improved survival.

HSCT??

See also

• Neutropenia
• Granulocyte colony-stimulating factor

References

• Klein, Christoph (2011). "Genetic Defects in Severe Congenital Neutropenia: Emerging Insights into Life and Death of Human Neutrophil Granulocytes". Annual Review of Immunology 29: 399–413. doi:10.1146/annurev-immunol-030409-101259. PMID 21219176. 

External links

• The European network Neutro-Net
• Dale, David C. (July 2011). ELANE-Related Neutropenia. NBK1533.  In Pagon RA, Bird TD, Dolan CR; et al. (eds.). GeneReviews™ [Internet]. Seattle WA: University of Washington, Seattle.  CS1 maint: Multiple names: editors list (link)
• Severe Congenital Neutropenia research study of Inherited Bone Marrow Failure Syndromes (IBMFS)
• Medicine Net
• Severe congenital neutropenia at NIH's Office of Rare Diseases
• Severe Chronic Neutropenia International Registry
• Deotare UR, Patel PD, Parikh RP, Bhagat EA (January 2012). "Uncommon cause of recurrent infections". Indian J Med Paediatr Oncol 33 (1): 51–3. doi:10.4103/0971-5851.96971. PMC 3385280. PMID 22754210.  CS1 maint: Multiple names: authors list (link)