Congenital and Acquired Neutropenia

Our understanding of the pathogenesis of congenital and acquired neutropenia is rapidly evolving. New ground-breaking observations have identified the genes responsible for many of the congenital neutropenia syndromes and are also providing new insights into normal neutrophil commitment and differentiation. Acquired neutropenia remains a poorly understood syndrome, although new insights into its pathogenesis are also emerging, especially with regard to subsets of immune neutropenia. In Section I, Dr. Marshall Horwitz reviews the current understanding of the genetic basis, molecular pathology, and approaches to treatment of congenital neutropenia and cyclic hematopoiesis. Mutations in the ELA2 gene, which encodes for neutrophil elastase, cause cyclic hematopoiesis. ELA2 mutations are also the most common cause of congenital neutropenia, where their presence may equate with a more severe clinical course and higher frequency of leukemic progression. Emerging evidence indicates interrelatedness with Hermansky Pudlak syndrome and other disorders of neutrophil and platelet granules. In Section II, Dr. Nancy Berliner presents an overview of the clinical approach to the evaluation and treatment of acquired neutropenia. This includes a review of the pathogenesis of primary and secondary immune neutropenia, drug-induced neutropenia, and non-immune chronic idiopathic neutropenia of adults. Studies used to evaluate patients for potential immune neutropenia are reviewed. Management issues, especially the use of granulocyte colony-stimulating factor (G-CSF), are discussed. In Section III, Dr. Thomas Loughran, Jr., reviews the pathogenesis and clinical manifestations of large granular lymphocyte (LGL) leukemia. Possible mechanisms of neutropenia are discussed. In particular, discussion focuses on the relationship between LGL leukemia, rheumatoid disease, and Felty’s syndrome, and the complex interplay of defects in neutrophil production, distribution, destruction, and apoptosis that underly the development of neutropenia in those syndromes.

Inherited Neutrophil Disorders

Recent advances in our understanding of the molecular basis of inherited neutrophil disorders and complementary studies in transgenic mouse models have provided new insights into the normal mechanisms regulating myelopoiesis and the functional responses of mature neutrophils. Neutrophil specific granule deficiency is a rare disorder of neutrophil function characterized by a lack of neutrophil secondary granule proteins and associated with recurrent bacterial infections. The CCAAT/enhancer binding protein (C/EBP) ϵ, a leucine zipper transcription factor expressed primarily in myeloid cells, and C/EBPϵ-deficient mice generated by gene targeting lack specific granules and have impaired host defense are discussed by Dr. Lekstrom-Himes in Section I. The similarity between these phenotypes led to the identification of a loss of function mutation in the C/EBPϵ gene in a subset of patients with specific granule deficiency. Dr. Dale reviews the clinical features and management of congenital neutropenia and cyclic hematopoiesis in Section II. Inherited mutations in the neutrophil elastase gene have recently been identified in both disorders. Specific mutations identified in cyclic and congenital neutropenia are described along with possible mechanisms for regulation of hematopoiesis by neutrophil elastase. In Section III, Dr. Dinauer reviews the molecular genetics of chronic granulomatous disease and studies in knockout mouse models. This work has revealed important features of the regulation of the respiratory burst oxidase and its role in host defense and inflammation. Results from preclinical studies and phase 1 clinical trials for gene therapy for CGD are summarized, in addition to alternative approaches using allogeneic bone marrow transplantation with nonmyeloablative conditioning.

Inherited Neutrophil Disorders

Recent advances in our understanding of the molecular basis of inherited neutrophil disorders and complementary studies in transgenic mouse models have provided new insights into the normal mechanisms regulating myelopoiesis and the functional responses of mature neutrophils. Neutrophil specific granule deficiency is a rare disorder of neutrophil function characterized by a lack of neutrophil secondary granule proteins and associated with recurrent bacterial infections. The CCAAT/enhancer binding protein (C/EBP) ϵ, a leucine zipper transcription factor expressed primarily in myeloid cells, and C/EBPϵ-deficient mice generated by gene targeting lack specific granules and have impaired host defense are discussed by Dr. Lekstrom-Himes in Section I. The similarity between these phenotypes led to the identification of a loss of function mutation in the C/EBPϵ gene in a subset of patients with specific granule deficiency. Dr. Dale reviews the clinical features and management of congenital neutropenia and cyclic hematopoiesis in Section II. Inherited mutations in the neutrophil elastase gene have recently been identified in both disorders. Specific mutations identified in cyclic and congenital neutropenia are described along with possible mechanisms for regulation of hematopoiesis by neutrophil elastase. In Section III, Dr. Dinauer reviews the molecular genetics of chronic granulomatous disease and studies in knockout mouse models. This work has revealed important features of the regulation of the respiratory burst oxidase and its role in host defense and inflammation. Results from preclinical studies and phase 1 clinical trials for gene therapy for CGD are summarized, in addition to alternative approaches using allogeneic bone marrow transplantation with nonmyeloablative conditioning.

Long-term treatment of canine cyclic hematopoiesis with recombinant canine stem cell factor

Grey collie dogs have cyclic fluctuations in their blood cell counts caused by a regulatory defect of hematopoietic stem cells. To examine the role of stem cell factor (SCF) or its receptor in this disorder, we investigated the stimulatory effects of recombinant canine SCF (rc-SCF) on in vitro marrow cultures, cloned and sequenced the grey collie SCF gene, and treated three grey collies with rc-SCF, either alone or in combination with recombinant canine granulocyte colony-stimulating factor (rcG-CSF). Colony-forming unit granulocyte-macrophage formation from grey collie or normal dog marrow showed similar dose-response curves for rc-SCF. Cloning and sequencing the SCF gene for two grey collies showed no evidence of mutations in the coding region of the SCF gene. Treatment with rc-SCF (10 to 100 micrograms/kg/d) did not induce neutrophilia except at the highest dose (100 micrograms/kg/d), but daily rc-SCF abrogated the neutropenic periods in doses of 20 micrograms/kg/d or greater. Combination of rc-G-CSF (0.5 to 1.0 microgram/kg/d) with rc-SCF treatment (20 to 50 micrograms/kg/d) suggested a synergistic effect, ie, the neutrophil levels on combined therapy were higher than the sum of the levels when these two cytokines were given separately. Long-term treatment of these dogs with rc-SCF in doses of 10 to 30 micrograms/kg/d was generally well tolerated, suggesting that SCF may be useful as a therapy for some chronic hypoproliferative disorders of hematopoiesis.

Contrasting effects of recombinant human granulocyte-macrophage colony- stimulating factor (CSF) and granulocyte CSF treatment on the cycling of blood elements in childhood-onset cyclic neutropenia

Recombinant human granulocyte colony-stimulating factor (G-CSF) treatment has been shown to increase average neutrophil counts substantially in patients with childhood-onset cyclic neutropenia (or “cyclic hematopoiesis”), but not to eliminate the cyclic oscillations of neutrophil counts or those of other blood elements (monocytes, platelets, eosinophils, and reticulocytes) that are characteristic of this hematopoietic disorder. Indeed, oscillations of neutrophil counts are amplified during G-CSF treatment. We have compared the effects of recombinant granulocyte-macrophage-CSF (GM-CSF) with those of G-CSF in three patients with this disease (2 men and 1 woman, 17, 30, and 32 years of age). These patients were treated with GM-CSF (2.1 micrograms/kg/day, subcutaneously) for 6 weeks, preceded and followed by 6 to 13 weeks of detailed observation to document changes in the cyclic oscillations of blood neutrophils and other blood elements; two of the patients were subsequently treated with G-CSF (5.0 micrograms/kg/d, subcutaneously) and observed for comparable periods of time. Unlike G-CSF treatment, which increased average neutrophil counts more than 20-fold, GM-CSF increased neutrophil counts only modestly, from 1.6- to 3.9-fold, although eosinophilia of varying prominence was induced in each patient. However, at the same time, GM-CSF treatment dampened or eliminated the multilineage oscillations of circulating blood elements (neutrophils, monocytes, platelets, and/or reticulocytes) in each of the patients. In contrast, G-CSF treatment of the same patients markedly amplified the oscillations of neutrophil counts and caused the cycling of other blood elements (monocytes in particular) to become more distinct. These findings support the conclusion that the distinctive cycling of blood cell production in childhood-onset cyclic neutropenia results from abnormalities in the coordinate regulation of both GM-CSF-responsive, multipotential progenitor cells and G-CSF-responsive, lineage-restricted, neutrophil progenitors.