High correlation of the proteome patterns in bone marrow and peripheral blood blast cells in patients with acute myeloid leukemia

Acute myeloid leukemia (AML) is an aggressive hematological neoplasia and it is characterized by accumulating myeloid precursor cells in bone marrow and detection of such cells in peripheral blood. Cytogenetics and molecular diagnostics are helpful for an individualized therapy in certain subsets of AML. There is hope that proteomics in AML will prompt new diagnostic or therapeutic biomarkers in future [1]. Up to date, the contribution of proteomics to the management of patients with AML is negligible although an enormous effort has been undertaken to develop databases of cancer proteins detected by two-dimensional gel electrophoresis [2]. They contain 2-D patterns and information from patients with lymphoproliferative disorders, leukemia, and a variety of other cell populations [3‐6]. These databases were developed primarily from in vitro cell cultures. Experiences with corresponding in vivo samples are rare, even though cells from hematological disorders can easily be obtained for protein analysis. First investigations referring to the proteome of leukemia in vivo were undertaken from Hanash in the middle 80's. Hanash screened polypeptides as markers to distinguish acute lymphoblastic leukemia (ALL) cell lineages [7]. Later the proteomic approach was used to identify Hsp27, which distinguishes between ALL in infants and older children [8, 9]. Recently, Balkhi and co-workers were able to identify significant differences in the AML proteome between cytogenetic groups of this disease. They postulated, that analysis of the post-translational modifications could be useful to distinguish different subgroups of AML [10].

Studies employing immunophenotyping methods in acute myeloid leukemias (AML) have shown a strong correlation of surface antigen expression comparing bone marrow and peripheral blood blast cells [11]. However, it remains unclear, whether there are differences in expression levels on either protein or RNA-level which may indicate biological differences for both cell types.

In the present study, we aimed to investigate the profile of protein expression of blast populations from peripheral blood and bone marrow aspirates using a proteomic approach with 2D-electrophoresis in newly diagnosed patients with AML.

We previously used a cell culture model derived from thermoresistant gastric cancer to build up a database for 2D-electrophoresis patterns [17]. After matching the gel images of the AML samples with the images of the gastric cancer cell line, we found some differences in the protein patterns but overall, these changes were small: Seven proteins (with two variants) were clearly defined in the gastric carcinoma cell line but not in the AML samples (Spots-No. 4, 64, 103, 108, 114, 121, 123) (Table 3). The majority of these proteins have unspecific or unknown functions or they are clearly related to tissues and not to hematological cells [18‐23].

As an example, protein spot No. 4 (14-3-3σ) is a family member of proteins that regulate cellular activity by binding and sequestering phosphorylated proteins. 14-3-3σ promotes pre-mitotic cell-cycle arrest following DNA damage, and its expression can be controlled by the p53 tumor-suppressor gene [24]. None of the investigated AML-samples exhibited a 14-3-3σ expression in the 2D pattern. Analysis of other AML samples which did not meet the inclusion criteria for this investigation showed similar results: the expression of 14-3-3σ in AML blast is an infrequent event. This observation corresponds to investigations in breast cancer and small cell lung carcinoma. In breast cancer a hypermethylation of the CpG island of the σ gene was found that leads to gene silencing and absence of 14-3-3σ. The authors conclude, that the loss of σ expression contributes to malignant transformation by impairing the G₂ cell cycle checkpoint function, thus allowing an accumulation of genetic defects [25, 26].

Interestingly, there were only marginal differences in the expression profiles comparing patient to patient. This was also observed in studies with patients with B-cell chronic lymphocytic leukemia (CLL). In CLL, analysis allowed the identification of proteins that clearly discriminated between the patients groups with defined chromosomal characteristics or clinical parameters such as patient survival [27].

Expression of the plasminogen activator inhibitor-2 (PAI-2) was only found in patients E and F with the subtyp FAB M0 and M4, respectively. This finding is inline with data from the PAI-2 serum levels of patients with hematological malignancies, where different expression levels were correlated with different serum levels for PAI-2 in the AML subtypes FAB M4 and M0 [28]. As an explanation it was postulated, that myeloid blasts, like their non-tumoral counterparts, monocytes/macrophages, are able to synthesize most components of the plasminogen activation system. Among the numerous features shared by normal monocytes and M4 cells were the capability to migrate to areas of inflammation and to infiltrate extramedullary tissues like gingival enlargement [29].

Furthermore, we have observed that the protein patterns from samples from bone marrow and peripheral blood from the same patient show a high correlation. The observed changes are marginal and inter-individually variable.

In conclusion, the protein expression profile in AML blasts collected from bone marrow aspirates in comparison to blasts from peripheral blood samples do not differ basically. This may indicate, that samples of peripheral blood with high amounts of blasts are to be considered suitable for investigations of the proteome using 2D-electrophoresis. Furthermore, protein expression profiling is likely to further impact the analysis of mechanisms involved in acute leukemia by examining routinely available biological material.

¹%T = [(acrylamide + bis-acrylamide) × 100]/total weight

%C = (bis-acrylamide × 100)/(bis-alcrylamide + acrylamide)