Large granular lymphocytic leukemia

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Large granular lymphocytic leukemia
Specialty Hematology, oncology

Large granular lymphocytic (LGL) leukemia is a chronic lymphoproliferative disorder that exhibits an unexplained, chronic (> 6 months) elevation in large granular lymphocytes (LGLs) in the peripheral blood. [1]

Contents

It is divided in two main categories: T-cell LGL leukemia (T-LGLL) and natural-killer (NK)-cell LGL leukemia (NK-LGLL). As the name suggests, T-cell large granular lymphocyte leukemia is characterized by involvement of cytotoxic-T cells). [2]

In a study based in the US, the average age of diagnosis was 66.5 years [3] whereas in a French study the median age at diagnosis was 59 years (with an age range of 12–87 years old). [4] In the French study, only 26% of patients were younger than 50 years which suggests that this disorder is associated with older age at diagnosis. [4] Due to lack of presenting symptoms, the disorder is likely to be underdiagnosed in the general population. [5]

Signs and symptoms

This disease is known for an indolent clinical course and incidental discovery. [1] The most common physical finding is moderate splenomegaly. B symptoms are seen in a third of cases, and recurrent infections due to anaemia and/or neutropenia [6] are seen in almost half of cases. [7] [8] [9] [10]

Rheumatoid arthritis is commonly observed in people with T-LGLL, leading to a clinical presentation similar to Felty's syndrome. [11] Signs and symptoms of anemia are commonly found, due to the association between T-LGLL and erythroid hypoplasia. [12]

Sites of involvement

The leukemic cells of T-LGLL can be found in peripheral blood, bone marrow, spleen, and liver. Nodal involvement is rare. [1] [7]

Cause

The postulated cells of origin of T-LGLL leukemia are transformed CD8+ T-cell with clonal rearrangements of β chain T-cell receptor genes for the majority of cases and a CD8- T-cell with clonal rearrangements of γ chain T-cell receptor genes for a minority of cases. [1]

Diagnosis

Laboratory findings

The requisite lymphocytosis of this disease is typically 2-20x109/L. [12]

Immunoglobulin derangements including hypergammaglobulinemia, autoantibodies, and circulating immune complexes are commonly seen. [10] [13] [14] [15]

Peripheral blood

The neoplastic lymphocytes seen in this disease are large in size with azurophilic granules that contains proteins involved in cell lysis such as perforin and granzyme B. [16] Flow cytometry is also commonly used. [17]

Bone marrow

Bone marrow involvement in this disease is often present, but to a variable extent. Bone marrow biopsy is commonly used for diagnosis. The lymphocytic infiltrate is usually interstitial, but a nodular pattern rarely occurs. [1]

Immunophenotype

The neoplastic cells of this disease display a mature T-cell immunophenotype, with the majority of cases showing a CD4-/CD8+ T-cell subset immunophenotype versus other permutations of those markers. [8] [9] Variable expression of CD11b, CD56, and CD57 [10] are observed. Immunohistochemistry for perforin, TIA-1, and granzyme B are usually positive. [1]

TypeImmunophenotype
Common type (80% of cases) CD3+, TCRαβ+, CD4-, CD8+
Rare variants CD3+, TCRαβ+, CD4+, CD8-
CD3+, TCRαβ+, CD4+, CD8+
CD3+, TCRγδ+, CD4 and CD8 variable

Genetic findings

Clonal rearrangements of the T-cell receptor (TCR) genes are a necessary condition for the diagnosis of this disease. The gene for the β chain of the TCR is found to be rearranged more often than the γ chain. of the TCR. [14] [18]

Current evidence suggests that patients with STAT3 mutations are more likely to respond to methotrexate therapy. [19]

Treatment

First line treatment is immunosuppressive therapy. A weekly dosage of Methotrexate (with or without daily Prednisone) may induce partial or complete response in some patients while others may require Cyclosporine or Cyclophosphamide. [6]

Alemtuzumab has been investigated for use in treatment of refractory T-cell large granular lymphocytic leukemia. [20]

Experimental data suggests that treatment with calcitrol (the active form of vitamin D) may be useful in treating T-cell LGL due to its ability to decrease pro-inflammatory cytokines. [21]

Prognosis

The 5 year survival has been noted as 89% in at least one study from France of 201 patients with T-LGL leukemia. [4]

Epidemiology

T-LGLL is a rare form of leukemia, comprising 2-3% of all cases of chronic lymphoproliferative disorders.[ citation needed ]

History

LGLL was discovered in 1985 by Thomas P. Loughran Jr. while working at Fred Hutchinson Cancer Research Center. [22] Specimens from patients with LGLL are banked at the University of Virginia for research purposes, the only bank for such purposes. [23]

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  22. "Archived copy" (PDF). Archived from the original (PDF) on 2016-12-21. Retrieved 2016-12-12.{{cite web}}: CS1 maint: archived copy as title (link)
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