Myelodysplastic syndrome pathophysiology

Pathophysiology
MDS is thought to arise from mutations in the multi-potent bone marrow stem cell, but the specific defects responsible for these diseases remain poorly understood. Differentiation of blood precursor cells is impaired, and there is a significant increase in levels of cell death apoptosis in bone marrow cells. Clonal expansion of the abnormal cells results in the production of cells which have lost the ability to differentiate. If the overall percentage of bone marrow blasts rises over a particular cutoff (20% for WHO and 30% for FAB) then transformation to leukemia (specifically acute myelogenous leukemia or AML) is said to have occurred. The progression of MDS to leukemia is a good example of the multi-step theory of carcinogenesis in which a series of mutations occur in an initially normal cell and transform it into a cancer cell. The mechanism involved was initially thought to be an increase in apoptosis but, as the disease progresses, more cytogenetic damage occurs. This eventually heralds a decrease in apoptosis leading to leukemia (showing abnormal clones with point mutations in Nras and AML1).

While recognition of leukemic transformation was historically important (see History), a significant proportion of the morbidity and mortality attributable to MDS results not from transformation to AML but rather from the cytopenias seen in all MDS patients. While anemia is the most common cytopenia in MDS patients, given the ready availability of blood transfusion MDS patients rarely suffer injury from severe anemia. However, if an MDS patient is fortunate enough to suffer nothing more than anemia over several years, they then risk iron overload. The two most serious complications in MDS patients resulting from their cytopenias are bleeding (due to lack of platelets) or infection (due to lack of white blood cells).

The recognition of epigenetic changes in DNA structure in MDS has explained the success of two of three commercially available medications approved by the US FDA to treat MDS. Proper DNA methylation is critical in the regulation of proliferation genes, and the loss of DNA methylation control can lead to uncontrolled cell growth, and cytopenias. The recently approved DNA methyltransferase inhibitors take advantage of this mechanism by creating a more orderly DNA methylation profile in the hematopoietic stem cell nucleus, and thereby restore normal blood counts and retard the progression of MDS to acute leukemia.

Some authors have proposed that the loss of mitochondrial function over time leads to the accumulation of DNA mutations in hematopoietic stem cells, and this accounts for the increased incidence of MDS in older patients. Researchers point to the accumulation of mitochondrial iron deposits in the ringed sideroblast as evidence of mitochondrial dysfunction in MDS.