WO2015167210A1 - Method for predicting prognosis of acute myeloid leukemia relapse - Google Patents

Abstract

The present invention relates to a method for predicting the prognosis of acute myeloid leukemia relapse. According to the present invention, the prognosis of acute myeloid leukemia relapse can be predicted by analyzing changes in a bone marrow microenvironment during the early diagnosis of leukemia.

Description

Prognostic Methods of Acute Myeloid Leukemia Recurrence

The present invention relates to a method for predicting prognosis of acute myeloid leukemia recurrence.

Leukemia is a general term for diseases in which leukocytes proliferate into tumors. Types of leukemias are classified into myeloid leukemia and lymphocytic leukemia according to the leukocytes from which leukemia originated, and are classified into acute leukemia and chronic leukemia according to the progress rate. The clinical manifestations of leukemia vary depending on the type of disease and the nature of the cells involved. Lymphoid leukemia is caused by mutations in lymphoid blood cells, myeloid leukemia in myeloid blood cells, and chronic myeloid leukemia in mature cells.Acute myeloid leukemia (AML) is a relatively early stage of the hematopoietic process. It is caused by a disorder of myeloid blast cells that begin to differentiate in. Acute myeloid leukemia usually occurs in adults and the elderly, and in children, about 10 to 15% of all leukemia patients. Acute lymphocytic leukemia mainly occurs in children, and is known to be the most frequent in children 2 to 10 years old. Chronic myeloid leukemia is more likely to occur in elderly people over 60 years, and chronic lymphocytic leukemia is a rare leukemia in Korea. Acute myeloid leukemia is known to account for about 70% of all acute leukemias.

Therapies for acute myeloid leukemia include chemotherapy, radiotherapy, or hematopoietic stem cell transplantation, and at first diagnosis, complete remission is usually induced by chemotherapy. By treatment after initial diagnosis, leukemia cells cannot be found on bone marrow and blood tests when complete remission is reached, but in theory there are still more than 100 million leukemia cells in the body. Therefore, acute myeloid leukemia has a high risk of recurrence even after complete remission, and acute myeloid leukemia is important for predicting the prognosis of relapse after remission.

Accordingly, the present invention is to provide a marker for predicting the prognosis of acute myeloid leukemia recurrence, a method for predicting the prognosis of acute myeloid leukemia recurrence using the marker and a method for providing information for predicting the prognosis of acute myeloid leukemia relapse.

The present invention provides a method for providing information for prognostic prediction of acute myeloid leukemia comprising analyzing the composition of stromal cells in a bone marrow sample obtained from a subject.

The present invention also provides a method for predicting the prognosis of acute myeloid leukemia comprising analyzing the composition of stromal cells in a bone marrow sample obtained from an individual.

According to the present invention, the prognosis of recurrence of acute myeloid leukemia can be predicted by analyzing the microenvironmental changes of bone marrow in the initial diagnosis of leukemia.

1A shows the comparison of mesenchymal cell composition in bone marrow of normal donors and AML patients (mean ± standard error of the mean, SEM = n = 51 for AML, n = 11 for normal donors).

1B shows the results of comparing the colony forming activity and proliferative capacity of mesenchymal cells in the bone marrow of donors and AML patients (n = 51 for AML and n = 11 for normal donors).

1C shows alteration of mesenchymal cells in BMs of patients following AMl subtypes by FAB sorting.

1D shows the number of AML-MSCs showing normal proliferation that continues to proliferate past two passages during passage 60 days in-vitro (n = 2 for normal donors and n = 5 for AML patients). .

FIG. 1E shows the comparison of senescence-associated beta-galactosidase activity of mesenchymal cells in the bone marrow of donors and AML patients (3 replicates, standard ± SEM, standard error of the mean) n = 12, n = 9 for normal donors.

FIG. 1F shows the results of comparing CFU-F numbers at initial diagnosis in bone marrow of normal donors and bone marrow of AML patients of the same age. Numbers in parentheses indicate mean age (n = 51 for AML and n = 11 for normal donors).

1G shows the results of comparing the number of CFU-F in the bone marrow of AML patients and normal donors after complete remission (n = 17 for AML remission group and n = 11 for normal donor).

2A is a schematic showing an experimental design for analysis of gene expression in MSCs co-cultured with AML blast cells or normal hematopoietic cells (n = 3 for each group).

2B shows the hierarchical clustering of various 1000 probes. (MAD> 0.04). Heatmaps represent relatively up- (red) and down- (blue) controlled portions.

2C shows the most important 10 GO categories up- and down-regulated in MSCs co-cultured with leukemia CD34 ⁺ cells as compared to MSCs co-cultured with normal CD34 ⁺ cells.

2D shows an enrichment plot of 105 'cell cycle'-associated gene sets.

FIG. 2E relates to the expression levels of cytokine-associated genes, showing the relative expression of 43 genes in the 'CHEMOKINE_RECEPTOR_BINDING' GO category (red for upregulation, blue for down regulation).

Figure 3a is a schematic diagram of the experiment of the expression change analysis of cross-talk molecules.

3B shows the results of analyzing the expression of jagged-1 or CXCL-12 proteins of normal and AML-MSCs (M2, M5a) in the presence or absence of normal CD34 ⁺ cells. (4 replicates, n = 4 for each group, *; p <0.05, ***; p <0.001).

3C shows the effect of co-culture of hematopoietic progenitor cells with normal or AML-MSCs on the down-flow Notch signal. Mean folds ± SEM of transcripts compared to levels in substrate-free (SF) conditions are shown (three replicates, n = 3 for each group).

3D shows the percent expression of jagged-1 in cultured normal or AML-MSCs (M2, M5a) in the presence or absence of leukemia blasts. (Mean ± SEM, 3 replicates, n = 3 for each group).

3E shows the results of analysis by flow cytometry of changes in expression of CXCL-12 in normal MSCs by co-culture with normal or leukemia blasts. The average percentage of CXCL-12 (+) cells in each group of MSCs is shown with SEM (three replicates, n = 3 for each group).

3F and 3G show the expression levels of jagged-1 (FIG. 3F) and CXCL-12 (FIG. 3G) in MSCs of fresh BMs in normal donors and AML patients in in-vivo (MSCs (CD45-31-235a) Mean% of jagged-1 (+) or CXCL-12 (+) cells, n = 8 for normal donors and n = 46 for AML).

Figure 3h shows the results of immunohistochemistry analysis of changes in the expression of jagged-1 or CXCL-12 in the BM compartment of AML patients during initial diagnosis and after remission. The portion labeled 'S' indicates a positively stained portion adjacent to the BM sinusoid in reticular cells. In addition, the arrow points to the positive staining portion and the dotted line portion to the enlarged area at high magnification (400X).

4A shows normal CD34 ⁺ cells of umbilical cord blood for 5 days in non-substrate conditions (SF), or for 5 days on two normal donors (# 1, # 2) derived MSCs or 4 AML patient derived leukemia MSCs. When incubated, the total expansion of CD34 ⁺ cells is shown (three replicates, mean SEM, n = 7, * p <0.05 for each group).

FIG. 4B shows the engraftment of BM cells into human hematopoietic cells (hCD45 +) after transplantation of normal CD34 + cells co-cultured with MSCs of each group into NSG mice treated with radiation (250 rad) (1 × 10 ⁴ CD34 + cells / mouse) Shows one result.

4C shows the results of LTC-ICs analysis in normal and AML-MSCs (after long-term incubation, the number of colonies from 400 CD34 ⁺ cells, 4 replicates, n = 4 for each group).

4D shows the effect on leukemia cell proliferation of normal or AML-MSCs (mean ± SEM, 3 replicates, n = 5-6 for each group).

4E shows the results of analysis of engraftment of leukemia cells (hCD45 +) in peripheral (PB) and BMs after transplantation of leukemia cells co-cultured with MSCs of each group (HL-60) into NSG mice treated with radiation. (Mean engraft% (SEM), n = 6 for each group).

FIG. 4F shows the cell cycle of leukemia cells (HL-60) co-cultured with MSCs in each group, showing the percentage of cell population at G ₀ phase by fluorescence / pyronin Y (Hoescht / Pyronin) staining. Analysis results are shown (mean SEM, 2 replicates, n = 2 for SF, n = 5-6 for co-culture group, * p <0.05).

Figure 4g shows the results of analysis of the cells in the process of apoptosis among the leukemia cells treated with Ara-C (2 uM) during co-culture by flow cytometry (mean ± SEM, 3 replicates, n = 3 for SF, n = 5-6 for co-culture group).

5A shows MSCs (CD45-31-235a-), endothelial cells (CD45-31-235a-31 +) (EC), MSC progenitors (CD45-31-235a-146 + 166-) (M-progenitors), The number of mature osteoblasts (CD146 + 31-235a-146-166 +) (OB), and CFU-Fs contained in 1 ml of fresh BM is shown.

FIG. 5B shows the results of analyzing the AUC values of BM stromal cell composition in order to verify its effectiveness as a biomarker for predicting acute myeloid leukemia recurrence of BM stromal cell composition (boxed if AUS value> 0.8) .

The top of FIG. 5C shows the number of biomarkers derived from FIG. 5B in CR and BM of various recurrences (95% confidence intervals). The bottom shows their Receiver operating characteristic (ROC) curves and AUC values (SE ).

5D shows the difference in stromal cell composition according to BM in CR and recurrent AML patients. The number of individual substrate compositions in the early relapse ( ≦ 1 year) and late relapse (> 1 year) groups is shown compared to the CR group (95% CI).

6 is a schematic diagram showing alterations of leukemia-induced niches and their clinical significance.

The pathogenesis of acute myeloid leukemia (AML) is known to be associated with changes in the microenvironment of bone marrow. When leukemic cells are produced by mutations in hematopoietic stem cells (HSCs), leukemia cells and leukemic stem cells (LSCs) change in the surrounding microenvironment, creating a leukemia state. Keep it. Through the following examples, the present inventors, these LSCs similar to normal HSCs, compete with the niche of normal HSCs when transplanted into mice, and moreover, leukemia cells transplanted into mice form abnormal bone marrow niches and are transplanted. It was confirmed that normal HSCs were replaced with tumor niches.

First, in order to determine whether the bone marrow microenvironment of acute myeloid leukemia patients is different from normal individuals, the composition of the mesenchymal stromal cells of the leukemia bone marrow and the normal bone marrow was analyzed and compared (Example 1). Acute myeloid leukemia bone marrow showed significant loss of mesenchyaml progenitors (M-progenitors) compared to normal bone marrow, but increased osteoblastic cells (OBs). In addition, acute myeloid leukemia bone marrow showed a decrease in colony forming ability and proliferative activity, and β-galactosidase activity was increased. This indicates that in leukemia bone marrow, mesenchymal differentiation has changed.

In order to confirm whether the above-described changes in the bone marrow microenvironment are caused by leukemia cells, the group of co-culture of leukemia cells and mesenchymal stromal cells, and the mesenchymal stromal cells of co-culture of normal cells and mesenchymal stromal cells Intragene expression patterns were analyzed (Example 2). As a result, in the group co-cultured with leukemia cells, an increase in gene expression related to cytokines and the like and a decrease in gene expression related to cell cycle or proliferation were observed. In addition, in order to confirm that leukemia cells cause cross-talk remodeling of niches, the expression pattern of cross-talk molecules was analyzed (Example 2). As a result, it was confirmed that in mesenchymal stromal cells co-cultured with leukemia cells, decreased expression of jagged-1, a crosstalk molecule, and increased expression of CXCL-12. These results suggest that leukemia cells cause changes in niches.

In addition, in order to determine whether such changes in niches affect the function of hematopoietic stem cells, the effects on normal hematopoietic function and leukemia function were analyzed. As a result, it was confirmed that normal hematopoietic action is suppressed due to the change of niche by leukemia cells. In addition, the change of niche by leukemia cells was found to act in the direction to increase the resistance to apoptosis and resistance to chemotherapy (Example 3). This suggests that leukemia cells remodel the substrate to favor normal survival of the leukemia cells while disrupting normal hematopoietic action.

Based on the above results, the present inventors have found that in acute myeloid leukemia, the leukemia cells change the niche of bone marrow, the change of niche changes the microenvironment in the bone marrow, and the change of the microenvironment is associated with the prognosis of We hypothesized that it would be relevant. It was confirmed through the following examples that the hypothesis is valid, to complete the invention.

Accordingly, the present invention provides a method of providing information for predicting the prognosis of acute myeloid leukemia recurrence comprising analyzing changes in the microenvironment in a bone marrow sample obtained from an individual. The invention also provides a method for predicting prognosis of acute myeloid leukemia recurrence comprising analyzing changes in the microenvironment in a bone marrow sample obtained from an individual. Changes in the microenvironment of the bone marrow can be confirmed by analyzing the composition of stromal cells in the bone marrow.

In the present invention, stromal cells refer to connective tissue cells of bone marrow and include undifferentiated mesenchymal stromal cells primitive mesenchymal stromal cells; P-MSCs), mesenchymal stromal cells (MSCs), mucosal osteoblastic cells (OB), and the like.

In one embodiment, analyzing the composition of stromal cells comprises analyzing at least one level selected from the group consisting of undifferentiated mesenchymal stromal cells, differentiated mesenchymal stromal cells and osteoblasts in a bone marrow sample obtained from an individual. can do. In one embodiment of the present invention, undifferentiated mesenchymal stromal cells, differentiated mesenchymal stromal cells and osteoblasts serve as markers for prognostic prediction of acute myeloid leukemia recurrence. Levels of undifferentiated mesenchymal stromal cells, differentiated mesenchymal stromal cells and osteoblasts can be analyzed by identifying the number of each cell. Analysis of the composition of stromal cells can be easily analyzed through flow cytometry performed during bone marrow examination for the diagnosis of acute myeloid leukemia.

In one embodiment of the invention, the subject is an acute myeloid leukemia candidate group, which may be an individual for early diagnosis of leukemia. According to the present invention, in the diagnosis of early acute myeloid leukemia, there is an advantage that can be predicted until the prognosis of future recurrence.

In one embodiment, the method may further comprise comparing the composition of the stromal cells in a bone marrow sample obtained from a subject without leukemia. In the present invention, a subject without leukemia refers to a subject in a normal state without leukemia and other diseases.

In one embodiment, a comparison of data from individuals without leukemia with acute myeloid leukemia candidate data indicates that the candidate group had a complete remission of acute myeloid leukemia when the undifferentiated mesenchymal stromal cells and differentiated mesenchymal stromal cells were reduced. Can be. In the present invention, complete remission refers to a case in which recurrence does not occur for a period of five or more years or five to eight years after the initial remission decision.

In one embodiment, the increase in undifferentiated mesenchymal progenitor cells may be indicative of early relapse within one year of acute myeloid leukemia.

In one embodiment, the increase in differentiated mesenchymal stromal cells and / or osteoblasts may be an indicator of recurrence of more than one year of acute myeloid leukemia.

In a cohort study, we found that remodeling of the stroma by leukemia cells is associated with the prognosis of acute myeloid leukemia recurrence (Example 4) .In early diagnosis, a high number of undifferentiated mesenchymal stromal cells in the bone marrow It was found that high numbers of differentiated mesenchymal stromal or osteoblasts were associated with late relapse. It was also confirmed that the reduction of undifferentiated mesenchymal stromal cells and differentiated mesenchymal stromal cells is an indicator of complete remission of acute myeloid leukemia. These results suggest that early and late recurrence of acute myeloid leukemia can be predicted through analysis of the substrate microenvironment in the early diagnosis of leukemia. According to the present invention, the bone marrow test performed during the initial diagnosis of leukemia can easily analyze the composition of stromal cells in the bone marrow, thereby predicting the possibility of future recurrence of acute myeloid leukemia.

Accordingly, the present invention provides a method for analyzing the composition of stromal cells in bone marrow to predict the prognosis of acute myeloid leukemia recurrence. The method for analyzing the composition of myeloid stromal cells may be applied or mutatis mutandis all described in the method for providing information for predicting the prognosis of acute myeloid leukemia recurrence.

The present invention also utilizes a high possibility of recurrence of acute myeloid leukemia when the number of leukemia cells affects the matrix of bone marrow, resulting in a large number of undifferentiated mesenchymal stromal cells, differentiated mesenchymal stromal cells and osteoblasts. Provided are methods for suppressing the recurrence of acute myeloid leukemia through suppression of the interaction between mesenchymal stromal cells and leukemia cells and providing information for suppressing the recurrence.

The present invention also provides a method for screening a relapse inhibitor of acute myeloid leukemia comprising treating a candidate and analyzing whether the candidate inhibits the interaction of leukemia cells with bone marrow stromal cells. If the treatment with the candidate substance inhibits the interaction of the leukemia cells with the myeloid stromal cells as compared to the control without the candidate substance, the candidate substance can be used as an inhibitor of relapse of acute myeloid leukemia.

Undifferentiated mesenchymal stromal cells are more likely to cause early relapse of acute myeloid leukemia, and increased numbers of differentiated mesenchymal stromal cells and / or osteoblasts are more likely to relapse at maturity. One or more inhibitors selected from the group consisting of inhibitors of stromal cells, differentiated mesenchymal stromal cells and osteoblasts can be used for the prevention of acute myeloid leukemia recurrence.

Hereinafter, the present invention will be described in detail through examples. The following examples are merely illustrative of the present invention, and the scope of the present invention is not limited to the following examples.

In the examples below all data were analyzed using a Statistical Analysis System (SAS), version 9.3; SAS Institute Inc., Cary, NC, USA, and the significance level was set to P <0.05.

Example 1 Confirmation of Mesenchymal Cell Changes in BMs of AML Patients

To determine potential changes in the bone marrow microenvironment of leukemia patients, we first analyzed the cell composition of bone marrow stromal cells without pretreatment in patients first diagnosed with acute myeloid leukemia (AML).

In all experiments, patients with acute myeloid leukemia without pretreatment after informed consent, as approved by a study by St. Mary's hospital and the Institutional Review Board of Seoul St. Mary's Hospital Bone marrow samples were obtained and used. Isolation of light-density mononuclear cells (MNCs) from bone marrow or leukapheresis samples of patients with acute myeloid leukemia by Ficoll-Paque gradient centrifugation And stored frozen for analysis. Umbilical cord blood cells from mothers or bone marrow from normal donors were similarly obtained after informed consent.

As a result of cell composition analysis, in the test of mesenchymal stromal cells (MSCs; CD45-31-235a-), acute myeloid leukemia bone marrow was expressed in mesenchyaml progenitors (M-progenitors; CD45-31-235a-146). Significant loss of + 166-) was observed, but mature osteoblastic cells (OBs; CD45-31-235a-146-166 +) increased compared to normal bone marrow (FIG. mesenchymal differentiation).

On the other hand, undifferentiated mesenchymal stromal cells are frequently expressed as colony forming cells (CFU-F) including niche cells in bone marrow, so that mesenchymal progenitor cells in normal and leukemia bone marrow Colony formation and self-renewal ability were examined. For CFU-F formation, BM MNCs were plated for 14 days (1 × 10 ⁶ cells / plate). Colonies were stained or subcultured with crystal violet. The percentage of BMs (no colony) that did not form colonies, colonies that formed colonies but reached growth arrest within 2 passages, and BMs (normal growth) that continued to grow after passage 3 were shown in FIG. n = 51; AML, n = 11; normal BM). Myeloid mononuclear cells (MNCs) from patients with acute myeloid leukemia frequently failed to form colonies (13.7% versus 0% for leukemia bone marrow and normal bone marrow, respectively) and aged-related β-galactosidase activity (senescence) Accelerated growth arrest within passages of subcultures associated with associated β-galactosidase activities is higher than normal bone marrow (33.3% versus 9.1% for acute myeloid leukemia and normal, respectively). Appeared (FIG. 1B).

In addition, colony forming ability (FIG. 1C) and proliferative capacity (FIG. 1D) of mesenchymal cells for AML subtypes according to FAB classification were examined.

As a result, alterations in mesenchymal stromal cell function were observed in patients with acute myeloid leukemia regardless of subtypes of acute myeloid leukemia (FIG. 1C). Even for acute myeloid leukemia-induced mesenchymal stromal cells (AML-MSCs) showing growth after three passages, more frequent decreases in proliferation were observed during 60 days of passage culture (FIG. 1D).

For self-renewal testing, assay for aging-associated β-galactosidase activity of culture-derived MSCs from 3 normal donors or 4 AML patients (including M1, M2, M5a, AML / myelodysplastic subtypes) (Normal; n = 9, AML; n = 12). Aging-associated β-galactosidase (SA-β-gal) activity was tested according to the manual using a kit (Cell Signaling, Danver, Mass.). The image is shown at the top of FIG. 1C and the mean ± SEM from the results of three replicate experiments is shown at the bottom. As shown in FIG. 1E, β-galactosidase activity was found to be higher in AML-MSC.

On the other hand, in order to determine whether such changes in mesenchymal cells are maintained after remission of AML, CFU-F at the time of initial diagnosis was compared and analyzed at a later time. As a result, although the total number of colony forming cells in acute myeloid leukemia bone marrow is lower than age-matched normal bone marrow, patients with acute myeloid leukemia reach complete remission (CR). In one case this difference was no longer observed (FIG. 1F, 1G). This means that alteration of mesenchyme in acute myeloid leukemia bone marrow reflects ongoing leukemogenic activities.

To determine whether the mesenchymal changes identified from the above experiment results directly in leukemic blasts, mesenchymal stromal cells were co-cultured with normal CD34 ⁺ cells or leukemia CD34 ⁺ cells for 5 days. The gene expression of the separated-purified cells was analyzed by separating-purifying from hematopoietic cells. Gene expression in mesenchymal stromal cells was analyzed by Illumina BeadChip array hybridization analysis. For six expression profiles, highly variable genes (ie, median absolute deviation top 1000 genes) for hierarchical clustering with median absolute deviation (MAD) and average linkage Was selected. Transcription profiles of mesenchymal stromal cells co-cultured with leukemia cells were compared to mesenchymal stromal cells co-cultured with hematopoietic progenitors (FIG. 2A).

Hierarchical clustering of highly variable genes clearly distinguished normal blast and leukemia blasts from mesenchymal stromal cells (FIG. 2B), showing substantial differences in transcriptomes.

Gene Set Enrichment Analysis, which analyzes the enrichment of functionally related gene sets from Gene Ontology (GO; MSigDB c5 categories) to identify the functions of candidate molecules associated with changes in these transcripts. ) Was performed. Significant normal P values were estimated from 1000 permutations of genes for each GO category. Multiple test adjustments were performed to select the meaningful (FDR <0.1) GO category. Overall, 11 and 80 GO categories showed significant (FDR <0.1) enrichment of up- and down-regulated genes in mesenchymal stromal cells co-cultured with leukemia CD34 ⁺ compared to normal CD34 ⁺ group ( 2c). Importantly, among the G0 categories down-regulated under leukemia conditions, significant enrichment of genes for 'cell-cycle' and its associated functions (eg, 'chromosome' and 'DNA replication') was observed. . This is consistent with the loss of proliferation in mesenchymal stromal cells from patients with acute myeloid leukemia. Enrichment plots of 105 'cell cycle'-associated gene sets were shown for the top 20 leading edge genes (FIG. 2D and Table 1). In contrast, among the up-regulated G0 categories in leukemia-cultured mesenchymal stromal cells, two cytokine-associated G0 functions were observed ('chemokine receptor binding' and 'chemokine activity') (FIG. 2C and FIG. 2e).

These results indicate that leukemia cells induce markedly different transcriptomic reprogramming from normal hematopoietic cells, accompanied by marked inhibition of cell-cycle associated genes and up-regulation of cytokine-associated genes.

Example 2 Re-establishment of Cross-Talk in the Microenvironment for Leukemia Niches and Normal Cells

To determine the alteration of leukemia-induced mesenchymal stromal cells, the expression changes of cross-talk molecules in mesenchymal stromal cells were examined. Mesenchymal expression of jagged-1 and CXCL-12 (+), cross-talk molecules that stimulate HSC self-renewal at niches, was examined during co-culture with normal cells and leukemia cells (FIG. 3A).

For analysis of fresh bone marrow stromal cells, bone marrow monocytes were stained with specific antibodies against subsets of mesenchymal cells and endothelial cells and analyzed by flow cytometry. Stain with goat anti-Jagged-1 antibody (Sigma-Adrich, St. Louis, MD) or mouse anti-CXCL12 / SDF-1 antibody (mouse anti-CXCL12 / SDF Flow cytometry of jagged-1 or CXCL-12 expression in fresh mesenchymal stromal cells was performed by intracellular staining with -1 antibody (R & D system, Minneapolis, Minn.). For cultured mesenchymal stromal cells, jagged-1 was detected by intracellular staining with rabbit anti-jagged-1 antibody (Cell Signaling). For immunohistochemistry, deparaffinize the bone marrow sections and use the SPlink HRP Detection Bulk Kit (Golden Bridge International, Mercalthio, WA). Immunohistochemical staining was performed. The rabbit jagged-1 and CXCL-12s in bone marrow fragments were detected by the rabbit anti-jagged-1 antibody (cell staining company) or mouse anti-CXCL12 / SDF-1 antibody that detects the intracellular domain of each molecule ( R & D System Co., Ltd.). Sections were visualized by counterstain with 3,3'diaminobenzidine substrate and hematoxylin.

As a result, in response to co-culture with normal hematopoietic progenitor cells, normal mesenchymal stromal cells showed a sharp increase in jagged-1 (+) cells, while acute myeloid leukemia-mesenchymal stromal cells further reduced it. To show an apparent response of acute myeloid leukemia-mesenchymal stromal cells in the opposite direction (FIG. 3B). Thus, normal hematopoietic progenitor cells co-cultured with acute myeloid leukemia-mesenchymal stromal cells are down-stream notch signals, Hes-1, compared to co-culture with normal mesenchymal stromal cells. Or significant inhibition of Hes-5 (FIG. 3C). In contrast, during co-culture with leukemia blasts, not only did jagged-1 (+) cells increase in normal mesenchymal stromal cells, but no decrease in acute myeloid leukemia-mesenchymal stromal cells was observed. (FIG. 3D), leukemia blasts and normal hematopoietic progenitor cells are shown to be involved in separate cross-talk under the leukemia microenvironment. Similarly, acute myeloid leukemia-mesenchymal stromal cells, when co-cultured with normal cells or leukemia cells, were examined for changes in mesenchymal stromal cells in CXCL-12 (+) cells. In response to selective selective CXCL-12 (+) cells, while decreasing during co-culture to normal hematopoietic cells (FIG. 3E).

To further explore these findings under leukemia in vivo, BMs of AML patients were screened for cross-talk molecules in fresh, non-cultured mesenchymal stromal cells. AML BMs showed a marked decrease in the percentage of jagged-1 (+) cells among mesenchymal stromal cells compared to normal bone marrow (5.4 ± 1.0 versus 0.5 ± 0.2% for normal and acute myeloid leukemia, respectively) (FIG. 3F). ). Similarly, the CXCL-12 (+) cells in mesenchymal stromal cells increased significantly among acute myeloid leukemia bone marrow compared to normal bone marrow (42.0 ± 5.2 vs. 69.9 ± 2.8% for normal and acute myeloid leukemia, respectively) (FIG. 3G), reproduced the changes in the cross-talks observed from the in vitro model. Interestingly, these changes observed in the initial diagnosis, such as a decrease in jagged-1 (+) or an increase in CXCL-12 (+) mesenchymal stromal cells, were analyzed after the bone marrow of the same patients reached complete remission Reversed (Fig. 3H). This means that leukemia cells cause remodeling of niche cross-talk as a unique part of leukemia progression.

Example 3 Functional impact of altered microenvironment to normal HSC

The effect of the modified microenvironment of mesenchymal stromal cells on the function of HSC in AML was investigated. To this end, leukemia mesenchymal stromal cells were co-cultured with normal or acute myeloid leukemia-mesenchymal stromal cells to analyze the effects of leukemia mesenchymal stromal cells on normal hematopoietic function or leukemia function.

Mesenchymal stromal cells were radiotreated (1500 centigray (cGy)) 24 hours prior to co-culture. And 100ng / ml human SCF, 100ng / ml human Flt3L and 20ng / ml human IL-3, IL-6, and G-CSF (ProSpec-Tany TechnoGene Ltd, Rehobot, Israel). In the presence of a cytokine mixture, the mesenchymal stromal cells were combined with normal or leukemia CD34 ⁺ cells in long-term culture-initiated cell medium (LTC-IC media; Stem Cell Technology H5100, Vancouver, Canada). Co-culture for 5 days.

Normal CD34 ⁺ cells from umbilical cord blood were stroma-free conditions (SF), co-cultured on MSCs from two normal donors (# 1, # 2) or leukemia MSCs conditions from four AML patients Incubated for 5 days and analyzed for the total increase in CD34 ⁺ cells (three replicates, n = 7 for each group). (*; p <0.05)

As a result, as shown in FIG. 4A, a significant ex vivo increase of CD34 ⁺ cells was observed when co-cultured on normal MSCs, but this increase was not observed when co-cultured on AML-MSCs.

Normal CD34 ⁺ cells co-cultured on each group of MSCs were transplanted into radiation treated (250 rad) NSG mice (1 × 10 ⁴ CD34 ⁺ cells / mouse). Eight weeks after transplantation, BM cells were analyzed for engraftment of human hematopoietic cells (hCD45 ⁺ ). NOD / SCID-γnull (NSG) mice were purchased from the Jackson Laboratory (Bar Harbor, Maine, USA) and stored in a filtered individual ventilation cage. For redistribution analysis, mice (7-10 weeks old) were treated with radiation (250 centigray) and hematopoietic cells were injected intravenously. Eight weeks after transplantation, human cell engraftment was analyzed by flow cytometry by staining.

As a result, in the left graph of FIG. 4B, the number of mice showing a positive response (when higher than 1%) among the total test mice is shown in parentheses. Mean human cell engraftment levels in normal and leukemia MSC groups are shown to the right of FIG. 4B (* p <0.05). As a result, when transplanted into NSG mice, normal hematopoietic progenitor cells co-cultured on AML-MSCs showed lower levels of repopulating activities compared to cells cultured on normal MSCs (FIG. 4B). .

For analysis of the maintenance of primitive hematopoietic cell populations by long-term culture-initiating cell (LTC-IC) assay, normal CD34 ⁺ cells co-cultured with individual MSCs After long-term incubation for 6 weeks, they were plated in semi-solid medium for colony formation. After long-term incubation, the number of 400 input CD34 ⁺ derived colonies was analyzed (4 experiments, n = 4 per group) and long-term culture-initiating cells in CD34 ⁺ cells co-cultured on AML-MSCs Huge losses were shown (FIG. 4C). In contrast, no loss was seen in the normal MSCs group. This means that AML-MSCs exert an inhibitory effect on normal hematopoietic action, and primitive hematopoietic cells are significantly affected by the adverse effects of leukemia mesenchymal stromal cells.

For 3 days, culture AML blasts (M1, M3, HL-60) under stroma-free conditions (SF), or co-culture with normal or AML-MSCs (M2, M5a), leukemia cells The number of (CD45 ⁺ ) was analyzed (3 experiments, n = 5-6 in each group). In addition, leukemia cells (HL-60) co-cultured with MSCs from each group were transplanted into radiation treated NSG mice. Six weeks after transplantation, the engraftment of leukemia cells (hCD45 ⁺ ) was analyzed in peripheral blood (PB) and BMs (n = 6 for each group).

As a result, there was no difference in in vitro proliferation or in vivo leukemogenesis, unlike long-term culture initiation cell analysis (FIG. 4D, FIG. 4E). This suggests that the leukemia cells are resistant to the adverse effects of leukemia niches.

In addition, the cell cycle of leukemia cells (HL-60) co-cultured with MSCs of each group by staining with fluorescence and pyronin (Hoescht and pyronin) was analyzed and% cell population at phase G ₀ (2 Experiment, SF; n = 2, co-culture group; n = 5-6).

During 2-day co-culture with MSCs of each group, leukemia cells (HL-60) were treated with Ara-C (2 uM) and, among leukemia cells (CD45 ⁺ ), apoptosis (Anxinxin + PPI-) process Cells in were analyzed by flow cytometry (three experiments, SF; n = 3, co-culture group; n = 5-6).

As a result, co-culture to the acute myeloid leukemia-mesenchymal stromal cells leads to a higher rate of leukemia cells than the co-culture to normal mesenchymal stromal cells and induced by Ara-C treatment. Higher resistance was given to apoptosis (FIG. 4F, FIG. 4G). At the same time, these results show that the leukemia microenvironment selectively inhibits normal hematopoietic cells, but has a pronounced effect on normal and leukemia cells in a manner that supports the leukemia activity and chemo-resistance of the leukemia cells. Indicates.

Example 4 Remodeling of niche as a prognostic parameter in leukemia patients

Discover the functional impact of stromal remodeling on normal hematopoietic action and leukemia-inducing activities, and hypothesize that differences in substrate remodeling may contribute to the heterogeneity in the clinical course of patients with acute myeloid leukemia. Built up. To test its potential, we designed a cohort study investigating the correlation between bone marrow matrix changes in the initial diagnosis of acute myeloid leukemia and their subsequent clinical processes over the next five to eight years. It was. For the cohort study, raw bone marrow samples from acute myeloid leukemia patients with complete follow-up data for 5 to 8 years after complete remission were collected (Table 2). Acute myeloid leukemia patient group (CR, n = 29) who remained in complete remission for 5 to 8 years after remission, then relapsed acute myeloid leukemia patient group (relapse; R; n = 14) and exhibited refractory to chemotherapy Stromal cell composition was examined with BM from normal donors (Nr; n = 12) for acute myeloid leukemia patient group (refractory; Rf; n = 5).

Although excessive heterogeneity was observed in patients with acute myeloid leukemia, significant differences were found in the matrix components of bone marrow. That is, undifferentiated mesenchymal stromal cells (CD45-31-235a-146 + 166-; P-MSCs) and colony forming cells in the bone marrow are lower than normal bone marrow regressed, whereas differentiated mesenchymal stromal cells (MSCs; CD45-31-235a-) and osteoblasts (CD146 + 31-235a-146-166 +; OB) were higher in the relapse group than in the complete remission group (FIG. 5A). However, there was no significant difference in the endothelial cell (EC; CD45-31-235a-31 +) content among the patient groups.

Therefore, to predict the recurrence of relapsed patients with acute myeloid leukemia, it was decided whether these differences in matrix patterns could be used to identify these high-risk patients. To this end, the predictability of recurrence for each substrate component was analyzed by applying a receiver operating characteristic (ROC) curve and the 'area under the curve' (AUC) measured thereby.

As a result, as shown in FIG. 5B, by differentiated mesenchymal stromal cells (0.78 ± 0.07), by undifferentiated mesenchymal stromal cells (0.72 ± 0.09) or osteoblasts (0.7 ± 0.09) The AUC values for prediction of the total relapse group by were higher than those by EC (0.63 ± 0.09) colony forming cells (0.68 ± 0/09) (FIG. 5B). Importantly, predictions for relapse have become more significant when separately analyzing early (within one year; n = 10) and late (more than one year; n = 4) recurrences. High numbers of undifferentiated mesenchymal stromal cells in the bone marrow indicate a high predictability of early relapse (within 1 year) (AUC = 0.8 ± 0.08) (FIGS. 5b and 5d), for relapse within 6 months after remission. Much more significant (AUC = 0.88 ± 0.06) (FIG. 5C).

In contrast, surprising differences were noted for patients with late relapse (more than 1 year), ie mesenchymal stromal cells differentiated in late relapse group compared to complete remission with high predictability for late relapse. Significantly high numbers of osteoblasts were observed (AUC = 0.91 ± 0.06 for differentiated mesenchymal stromal cells and AUC = 0.88 ± 0.08 for osteoblasts, respectively) (FIG. 5C).

These results were summarized and shown in the schematic diagram in FIG. In summary, high numbers of undifferentiated mesenchymal stromal cells in the bone marrow are highly associated with early relapse, while high numbers of differentiated mesenchymal stromal cells or osteoblasts are associated with late relapse. That is, early and late relapse of acute myeloid leukemia is clearly associated with the microenvironment of the substrate (FIG. 6).

Thus, the parameters for heterogeneity in the clinical course of acute myeloid leukemia can serve as potential biomarkers for the prediction of the clinical course of patients with acute myeloid leukemia and in the bone marrow of patients with acute myeloid leukemia in early diagnosis. Substrate changes suggest that this may be a parameter for heterogeneity in the clinical course of this acute myeloid leukemia.

Claims (14)

1. A method of providing information for predicting prognosis of acute myeloid leukemia relapse comprising analyzing the composition of stromal cells in a bone marrow sample obtained from a subject.
2. The method of claim 1 wherein the analysis of the composition of stromal cells comprises analyzing at least one level selected from the group consisting of undifferentiated mesenchymal stromal cells, differentiated mesenchymal stromal cells and osteoblasts in a bone marrow sample obtained from an individual. Providing information for predicting the prognosis of acute myeloid leukemia, including.
3. The method of claim 1, wherein the subject is an acute myeloid leukemia candidate group and provides information for predicting prognosis of acute myeloid leukemia recurrence that is an individual for early diagnosis of leukemia.
4. The method of claim 1, further comprising comparing the composition of the stromal cells in a bone marrow sample obtained from an individual without leukemia to provide a prognostic prediction for recurrence of acute myeloid leukemia.
5. The method of claim 2, wherein the reduction of undifferentiated mesenchymal stromal cells and differentiated mesenchymal stromal cells provides information for prognostic prediction of acute myeloid leukemia relapse, which is an indicator of complete remission of acute myeloid leukemia.
6. The method of claim 2, wherein the increase in undifferentiated mesenchymal stromal cells provides information for prognostic prediction of acute myeloid leukemia relapse, which is an indicator of early relapse within 1 year of acute myeloid leukemia.
7. The method of claim 2, wherein the increase in differentiated mesenchymal stromal cells and / or osteoblasts provides information for prognostic prediction of acute myeloid leukemia recurrence that is indicative of a more than one year late relapse of acute myeloid leukemia.
8. A method for predicting the prognosis of acute myeloid leukemia relapse comprising analyzing the composition of stromal cells in a bone marrow sample obtained from a subject.
9. The method of claim 8, wherein the analysis of the composition of the stromal cells comprises analyzing at least one level selected from the group consisting of undifferentiated mesenchymal stromal cells, differentiated mesenchymal stromal cells and osteoblasts in a bone marrow sample obtained from an individual. A method for predicting the prognosis of acute myeloid leukemia relapse, including.
10. The method of claim 8, wherein the subject is an acute myeloid leukemia candidate group and is a subject for early diagnosis of leukemia.
11. The method of claim 8, further comprising comparing the composition of stromal cells in a bone marrow sample obtained from an individual without leukemia.
12. The method of claim 9, wherein the reduction of undifferentiated mesenchymal stromal cells and differentiated mesenchymal stromal cells is an indicator of complete remission of acute myeloid leukemia.
13. 10. The method of claim 9, wherein the increase in undifferentiated mesenchymal stromal cells is indicative of the prognosis of acute myeloid leukemia relapse, which is indicative of early relapse within 1 year of acute myeloid leukemia.
14. The method of claim 9, wherein the increase in differentiated mesenchymal stromal cells and / or osteoblasts is indicative of acute myeloid leukemia recurrence that is indicative of a more than one year late relapse of acute myeloid leukemia.

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