‘Conservative’ and ‘variable’ clusters of Alu-family DNA repeats in human chromosomes

The distribution of Alu-family DNA repeats (AFRs) in chromosomes of phytohaemagglutinin-stimulated peripheral blood lymphocytes of four normal donors and non-stimulated bone marrow cells of four patients with acute leukemia (ALL and ANLL) was studied by in situ hybridization using DNA of recombinant phage lambda containing multiple inserts of AFR as a probe. Over some chromosome bands (14cen, 16p13, 16cen) from normal donors and from leukemic patients clusters of silver grains were detected. Over other three bands (3q26, 8p11-p12 and 14q24) the clusters were found only in chromosomes from the four acute leukemia patients, and were absent from chromosomes of healthy donors. The results suggest non-random long-range distribution of AFRs in human chromosomes, and somatic variations in the distribution of the repeats.     

Non-random distribution of Alu-family repeats in human chromosomes

A phage lambda recombinant clone containing at least 8 Alu-family repeats (AFRs) has been isolated from a human genomic library, and DNA from the phage was used as a probe for in situ hybridization on G-banded human metaphase chromosomes of healthy donors and leukemic patients. Some chromosome bands show prominent clusters of silver grains in all individuals examined: 1p34, 1q23, 2q21–22, 10p14, 11p14, 10q21 and 11q14. The data suggest non-random distribution of AFRs in the human genome.     

Fluorescent in situ hybridization (FISH) in bone marrow and peripheral blood of leukemia patients: implications for occupational surveillance

Although there has been a rapid rise in the application of fluorescent in situ hybridization (FISH) analysis of bone marrow tissue for the staging and prognosis determination of hematopoietic malignacies such as the chronic and acute leukemias, it's application as a surveillance tool for leukemogen exposed high risk occupational cohorts is understandably limited by the invasiveness of sample collection. While some small occupational studies have been performed using FISH in peripheral blood with promising results, some of the basic assumptions made in utilizing the FISH technique have not been fully explored. These include selection of the correct hematopoietic cell to assay (myeloid or lymphoid); selection of appropriate chromosomal markers and the sensitivity of peripheral blood FISH in detecting unbalanced genomic abnormalities. In this study, we performed a pilot 'validation' exercise utilizing the FISH technique and standard metaphase cytogenetics, comparing results in tandem pairs of peripheral blood with bone marrow cells, where clonal abnormalities arise. Samples were taken from patients with known chromosomal lesions associated with active leukemia. We carefully chose markers most frequently associated with leukemogen-inducing DNA damage and probes that have been utilized successfully in clinical practice. Ten de novo or therapy-related acute myeloid leukemia (t-AML) patients underwent bone marrow cell karyotyping and fluorescent in situ hybridization (FISH) analysis. Parallel peripheral blood samples were concommitently drawn and evaluated with FISH using the same probes. In six of eight paired samples treated with a 3-day phytohemagglutinin (PHA) stimulation, typically used to assay lymphocytes and their progenitors, we detected abnormal clones. In one of the two remaining cases, we identified an abnormal clone in both bone marrow and PHA-stimulated peripheral blood, although at a level in the peripheral blood sample that would typically be reported as "non-diagnostic" for clinical purposes. These results suggest that use of FISH in PHA stimulated peripheral blood samples with probes commonly employed in t-AML evaluations (chromosomes 5q, 7q, 8, 11q) to detect cytogenetic abnormalities in peripheral blood represents a potentially promising though as yet, under-utilized approach for the occupational surveillance of workers exposed to leukemogens, especially if it could be linked to automated high-throughput assays for increased sensitivity.     

Amplification of RNA and DNA specific for erb B in unbalanced 1;7 chromosomal translocation associated with myelodysplastic syndrome

Previous work has established the presence of an unbalanced chromosome abnormality [+der(1),t(1;7)(p11;p11)] in some therapy-associated myelodysplastic disorders. Recently the EGF receptor has been found to reside at 7p11. Using a probe specific for erb B oncogene, which encodes a truncated form of the EGF receptor, we examined RNA and DNA derived from bone marrow and peripheral blood mononuclear cells from three patients with myelodysplastic syndromes (MDS) and one with acute lymphocytic leukemia (ALL), all bearing an abnormal clone in their bone marrow with a similar unbalanced 1;7 translocation. DNA-excess slot blot hybridization to 5'-32p-labeled cellular RNA revealed from ten- to thirtyfold enhancement in accumulation of mRNA specific for erb B in both peripheral blood and bone marrow cells of the three MDS patients when compared to normal controls. In addition, enhancement of H-ras mRNA accumulation was detected in some, though expression of other genes such as actin, N-ras, myc, src, B-lym, and 20 other genes was not found to be enhanced. Increased erb B expression was not apparent in mononuclear cells from patients with other hematologic disorders such as chronic lymphocytic leukemia, Hodgkin's disease, or lymphoma. Southern blot analysis of restriction-enzyme-cleaved DNA from three MDS patients with an unbalanced 1;7 translocation revealed that erb B gene was amplified at least twentyfold in peripheral blood white blood cells, while levels of actin hybridization were comparable to those of the controls. No such amplification was evident in the ALL patient. Our data suggest that +der(1),t(1;7)(p11;p11) chromosomal anomalies can be specifically associated with amplification of erb B DNA and RNA sequences.     

Effect of thymic humoral factor in vitro on human bone marrow and blood cells from B-, T- and null-cell acute lymphatic leukemia.

The nature of null-cell acute lymphatic leukemia (ALL) was investigated with the aid of a thymic humoral factor (THF), bone marrow cells, and a local xenogeneic graft-versus-host reaction (GVHR). Lymphocytes obtained from the blood and bone marrow of six children with T-cell ALL, five with null-cell ALL, one with perinatal B-cell ALL, one with acute myelocytic leukemia, and one with erythroleukemia were tested for membrane surface markers (E, EAC, and SM Ig); functional activity of T cells was tested by a local GVHR. All of the specimens obtained at the initial presentation showed a lack of functional activity of the lymphocytes. Incubation of null cell and acute myelocytic leukemia (AML) bone marrow with THF led to the acquisition of the characteristics of functional, immunocompetent T cells. No such effect was seen when the bone marrow of T-cell ALL and peripheral blood lymphocytes of B-cell perinatal ALL were incubated with THF. This study demonstrates that the null cell in ALL bone marrow can be differentiated into a T cell whereas the stem cell in AML bone marrow constitutes a pluripotential undifferentiated cell which also can mature into a T cell.     

Direct versus cultured preparation of bone marrow cells from 22 patients with acute myeloid leukemia

Summary The 24-h culture of bone marrow from patients with acute myeloblastic leukemia (AML) and acute promyelocytic leukemia (APL) gave more analyzable metaphase cells and improved chromosome morphology compared with direct preparations. Culture increased the proportion of cytogenetically abnormal cells, and in six bone marrows where the direct preparation failed, a result was obtained from the cultured preparation. The culture of bone marrow from patients with APL led to the detection of clones carrying the t(15;17) that were not found in direct preparations. Such sequestered clones were not found in AML and acute myelomonocytic leukemia (AMMoL). Cultured preparations were no better than direct preparations from AMMoL.     

Consecutive chromosomal studies in patients with myelodysplastic syndrome (MDS). Czechoslovak MDS Cooperative Group.

In order to detect a possible relationship between clonal chromosomal abnormalities acquired during the course of the disease and its prognosis in patients with myelodysplastic syndrome (MDS) the authors have performed consecutive analyses in 77 patients with this disease. They were part of the large series of 209 patients cytogenetically examined during the last ten years. According to the cytogenetic findings we have distinguished three groups: 1) sixteen patients who has a normal karyotype in bone marrow cells at the beginning of the investigation and this finding remained unchanged during the course of the disease. Three of them progressed into acute leukemia (AL) without any detectable change in the chromosomal complement of the bone marrow cells; 2) twenty-five patients who had at the beginning of the study, different pathological chromosomal clones in bone marrow cells. There was no chromosomal evolution detectable during the disease; eight of them progressed into acute leukemia; 3) thirty-six patients who had either normal or pathological chromosomal findings at the first examination and in whom further clonal abnormalities had developed during the course of the disease. Twelve of them progressed into acute leukemia. Two to nine cytogenetic examinations were successfully performed with a mean of three studies per patient. The results confirmed strictly individual development of chromosomal abnormalities during the course of the disease, with an unfavorable prognosis for the patients with complex chromosomal changes. Three patients with del 7q had very poor prognosis with rapid progression of the disease. Two cases with the same acquired abnormalities (del 20q, +8, -22) transformed into acute leukemia within the period of 36 months from the onset of the disease.     

Hematopoietic stem cell expansion and distinct myeloid developmental abnormalities in a murine model of the AML1-ETO translocation

The t(8;21)(q22;q22) translocation, which fuses the ETO gene on human chromosome 8 with the AML1 gene on chromosome 21 (AML1-ETO), is one of the most frequent cytogenetic abnormalities associated with acute myelogenous leukemia (AML). It is seen in approximately 12 to 15% of AML cases and is present in about 40% of AML cases with a French-American-British classified M2 phenotype. We have generated a murine model of the t(8;21) translocation by retroviral expression of AML1-ETO in purified hematopoietic stem cells (HSC). Animals reconstituted with AML1-ETO-expressing cells recapitulate the hematopoietic developmental abnormalities seen in the bone marrow of human patients with the t(8;21) translocation. Primitive myeloblasts were increased to approximately 10% of bone marrow by 10 months posttransplant. Consistent with this observation was a 50-fold increase in myeloid colony-forming cells in vitro. Accumulation of late-stage metamyelocytes was also observed in bone marrow along with an increase in immature eosinophilic myelocytes that showed abnormal basophilic granulation. HSC numbers in the bone marrow of 10-month-posttransplant animals were 29-fold greater than in transplant-matched control mice, suggesting that AML1-ETO expression overrides the normal genetic control of HSC pool size. In summary, AMLI-ETO-expressing animals recapitulate many (and perhaps all) of the developmental abnormalities seen in human patients with the t(8;21) translocation, although the animals do not develop leukemia or disseminated disease in peripheral tissues like the liver or spleen. This suggests that the principal contribution of AML1-ETO to acute myeloid leukemia is the inhibition of multiple developmental pathways.     

Detection of trisomy 8 in hematological disorders by in situ hybridization

An alphoid repetitive DNA (D8Z2) probe specific for the pericentromeric region of chromosome 8 was used to detect extra copies of chromosome 8 in bone marrow cells obtained from 10 patients with hematological disorders and five controls. Numerical aberrations of chromosome 8 were established by conventional banding techniques. Trisomy 8 was found in four patients with myelodysplastic syndrome (MDS) and three with acute myeloid leukemia (AML). Three additional patients with MDS exhibited an extra chromosome 8 in only one metaphase. In five of the seven trisomy cases, the presence of the trisomy 8 clone was confirmed by in situ hybridization (ISH). In one case of AML with trisomy 8, detected by GTG-banding, no significant numbers of cells containing three spots were found using the alphoid repetitive probe; however, hybridization with a chromosome 8-specific library revealed that the alleged extra chromosome 8 was a translocation chromosome containing only the long arm of chromosome 8. Due to a lack of material, it was not possible to achieve optimal ISH results on the trisomy 8 bone marrow cells of patient 7. In the three MDS patients with a single trisomy 8 metaphase, a slight, albeit significant, increase of trisomy 8 interphase cells was found with ISH. We conclude that this probe is useful for cytogenetic studies. Moreover, ISH, in general, is a powerful tool for precise classification of chromosomal aberrations and can also contribute significantly to the clinical evaluation of patients with hematological disorders.     

Cloning of human myeloid-associated differentiation marker (MYADM) gene whose expression was up-regulated in NB4 cells induced by all-trans retinoic acid

A full-length cDNA of 3192 bp isolated from human bone marrow cDNA library was predicted an ORF encoding 298 amino acids. The deduced protein, containing seven putative transmembrane segments and sharing 75.8% amino acid identity with mouse Myadm protein, was named as human MYADM. The results of Northern blot analysis showed that MYADM was ubiquitously expressed in 15 of 16 adult tissues tested, except thymus. To determine whether the novel human gene was involved in hematopoietic differentiation process as mouse Myadm did, we examined the mRNA expressive abundance of this gene between normal bone marrow cells and peripheral blood leukocytes, and detected the expression change in NB4 cells induced by all–trans retinoic acid at different induce time by the semi-quantitative RT-PCR. The results showed that the expression of the novel gene was not only significantly higher in peripheral blood leukocytes than in bone marrow cells, but also significantly up-regulated when the NB4 cells(derived from a patient with acute promyelocytic leukemia) were induced by all-trans retinoic acid (ATRA) for 48hr. It is suggested that human MYADM was also associated with the differentiation of hematopoietic cells or acute promyelocytic leukemia cells. In addition, MYADM was mapped to human chromosome 19q13.33-q13.4 by Radiation Hybrid mapping, and it consists of 3 exons and 2 introns and spans a 7.1-Kb genomic region.     

Transplantation of hematopoietic stem cells from the peripheral blood

Hematopoietic stem cells can be collected from the peripheral blood. These hematopoietic stem cells (HSC), or better progenitor cells, are mostly expressed as the percentage of cells than react with CD34 antibodies or that form colonies in semi-solid medium (CFU-GM). Under steady-state conditions the number of HSC is much lower in peripheral blood than in bone marrow. Mobilization with chemotherapy and/or growth factors may lead to a concentration of HSC in the peripheral blood that equals or exceeds the concentration in bone marrow. Transplantation of HSC from the peripheral blood results in faster hematologic recovery than HSC from bone marrow. This decreases the risk of infection and the need for blood-product support. For autologous stem-cell transplantation (SCT), the use of peripheral blood cells has completely replaced the use of bone marrow. For allogeneic SCT, on the other hand, the situation is more complex. Since peripheral blood contains more T-lymphocytes than bone marow, the use of HSC from the peripheral blood increases the risk of graft-versus-host disease after allogeneic SCT. For patients with goodrisk leukemia, bone marrow is still preferred, but for patients with high-risk disease, peripheral blood SCT has become the therapy of choice.     

A new human T-cell differentiation antigen: Unexpected expression on chronic lymphocytic leukemia cells

Monoclonal antibody 10.2 reacts with a monomorphic antigen expressed on the surface of virtually all thymocytes, as well as thymus-dependent lymphocytes in the peripheral blood and bone marrow. In contrast, antibody 10.2 did not react with normal peripheral blood B cells, monocytes, or the non-T-cell fraction of bone marrow. This complement fixing IgG2a antibody also reacted with extablished leukemic T-cell lines, but not with cell lines of either normal or malignant B-cell origin. Similarly, when tested against acute leukemia blasts, the 10.2 antibody reacted with those from patients with T-cell acute leukemia, but not with those from patients with acute null cell or non-lymphocytic leukemia. An unexpected exception to this pattern was the reaction of 10.2 antibody with leukemic cells from patients with B-cell type chronic lymphocytic leukemia. Immune precipitates formed with 10.2 antibody and detergent lysates of radiolabeled T-cells contained three polypeptides with molecular weights of 65 000, 55 000, and 50000 daltons. It has not been determined whether all three of these polypeptides contain the 10.2 antigenic determinant, or whether these proteins represent a multimeric antigen complex.PJM is a Junior Faculty Clinical Fellow of the American Cancer Society.     

A new human T-cell differentiation antigen: unexpected expression on chronic lymphocytic leukemia cells

Monoclonal antibody 10.2 reacts with a monomorphic antigen expressed on the surface of virtually all thymocytes, as well as thymus-dependent lymphocytes in the peripheral blood and bone marrow. In contrast, antibody 10.2 did not react with normal peripheral blood B cells, monocytes, or the non-T-cell fraction of bone marrow. This complement fixing IgG2a antibody also reacted with established leukemic T-cell lines, but not with cell lines of either normal or malignant B-cell origin. Similarly, when tested against acute leukemia blasts, the 10.2 antibody reacted with those from patients with T-cell acute leukemia, but not with those from patients with acute null cell or non-lymphocytic leukemia. An unexpected exception to this pattern was the reaction of 10.2 antibody with leukemic cells from patients with B-cell type chronic lymphocytic leukemia. Immune precipitates formed with 10.2 antibody and detergent lysates of radiolabeled T-cells contained three polypeptides with molecular weights of 65 000, 55 000, and 50 000 daltons. It has not been determined whether all three of these polypeptides contain the 10.2 antigenic determinant, or whether these proteins represent a multimeric antigen complex.     

A comparison of the rate of DNA synthesis in myeloblasts from peripheral blood and bone marrows of patients with acute nonlymphocytic leukemia

Durations of S-phase (Ts) and total cell cycle times (Tc) were measured from the peripheral blood (PB) and bone marrow aspirates (BM) of five patients with acute nonlymphocytic leukemia (ANLL). Intravenous bromodeoxyuridine (BrdU) was used as the first label for S-phase cells and a monoclonal anti-BrdU antibody was used to detect the positive cells. Tritiated thymidine [( 3H]Tdr) was used as a second label in vitro, and the Ts was calculated by counting the number of cells labeled either by BrdU or by [3H]Tdr or by both. Our data demonstrate that the duration of S-phase in myeloblasts obtained from BM is quite similar to that of circulating leukemic cells. Finally, the most accurate assessment of percentage of myeloblasts actively engaged in DNA synthesis can be obtained only from bone marrow biopsies following in vivo labeling.     

In vitro growth of erythropoietic progenitor cells in long-term remission of acute leukemia

In vitro growth of CFU-e and BFU-e in bone marrow and of circulating BFU-e in a group of adult long-term survivors of acute leukemia has been evaluated. Six patients with acute nonlymphoblastic and three patients with acute lymphoblastic leukemia in first continuous remission for more than four years (range 4-12 years) and without maintenance therapy for at least one year were studied. BFU-e and CFU-e growth in patients' bone marrow was not statistically different from a control group of 12 healthy adult volunteers. However, proliferation of BFU-e in peripheral blood of patients was significantly reduced (p less than 0.001). This growth pattern was found in both lymphoblastic and myeloblastic leukemia.     

Growth of normal versus leukemic bone marrow cells in long term culture from acute lymphoblastic and myeloblastic leukemias

The ability of the in vitro long-term bone marrow culture (LTBMC) system to impair the survival of leukemic cells and to enhance the growth of normal progenitors has been studied. Bone marrow cells from 19 acute lymphoblastic leukemia (ALL) and 30 acute myeloid leukemia (AML) patients at diagnosis were grown in LTBMC for 4-10 weeks. In half of the cases the leukemic population declined down to undetectable levels and was replaced by putative normal hemopoietic precursors, both in ALL and in AML. In the remaining cases, leukemic cells persisted throughout the culture time and few if any normal hemopoietic cells were detected. These data led us to extend to the lymphoid compartment the previous observation of decreasing leukemic myeloid blasts in LTBMC. The potential of such cultures as an in vitro purging system for autologous bone marrow transplantation in selected poor-prognosis lymphoid malignancies should be explored, as has been done for acute and chronic myeloid leukemias.     

Antibody-producing human-human hybridomas. III. Derivation and characterization of two antibodies with specificity for human myeloid cells

Peripheral blood mononuclear cells from a patient with acute myeloid leukemia (AML) and spleen cells from a patient with chronic myeloid leukemia (CML) were fused with HAT-sensitive human B lymphoma cells (RH-L4) in attempts to generate human monoclonal antibodies (Mab) against antigens with high specificity for myeloid leukemia cells. Forty-seven of 246 hybridomas secreted Ig that bound to AML cell surface constituents, as determined by FACS analysis of viable cells that were FITC-stained with the human Mab as the first-step reagent and FITC-conjugated rabbit anti-human Ig as second-step. Two of the 47 human Mab (one from each patient and designated AML-19 and CML-20, respectively) bound to both autologous and allogeneic myeloid leukemia cells. No significant binding was observed to cell surface constituents on human bone marrow cells, granulocytes, lymphocytes, erythrocytes, thymocytes, monocytes, lymphoblastic leukemia cells, fibroblasts, malignant B and T lymphocytic cell lines, and murine bone marrow cells. Both human Mab were IgG and were cytotoxic to myeloid leukemia cells in the presence of complement. About 70% of peripheral blood cell samples from 46 AML patients contained AML-19- and CML-20-positive cells, but the reactivity pattern had no correlation to the morphologic FAB classification of the samples. The promyelocytic HL60 cell line and the K562 cell line reacted with the two antibodies. Dot blot analysis of binding of AML-19 and CML-20 to cellular extracts immobilized on nitrocellulose paper showed that both human Mab in this assay also reacted with normal bone marrow cells. This was supported by microscopic immunofluorescence because both human Mab stained intracytoplasmatic structures in normal bone marrow cells, but both intracytoplasmatic and cell surface components stained in myeloid leukemia cells. Moreover, immunoblotting demonstrated that both human Mab in leukemia cells reacted with two cellular proteins with Mr approximately 14,500 and 18,000, and in normal bone marrow cells with a molecule with Mr approximately 20,000. Immunoprecipitation of cell membrane molecules with both the AML-19 and CML-20 antibody precipitated from leukemic cells only the molecule with Mr approximately 18,000 and no components from normal bone marrow cells. It is concluded that myeloid leukemogenesis may result in generation of cell surface expression of either new or abnormally processed molecules that are immunogenic in the autochthonous host. These molecules may also be useful as markers in diagnosis of myeloid leukemia.     

Use of nanocolonies to detect minimal residual disease in patients with leukemia t(8;12)

Molecular Biology - A complete diagnostic procedure was developed to detect single molecules of the AML1-ETO mRNA in whole blood and bone marrow samples of leukemia t(8;21)(q22;q22) patients. The...     

Stimulant of antibody producers isolated from the supernatants of cell cultures of normal human bone marrow and in various diseases

The biological activity of a stimulant of antibody producers (SAP) isolated from normal human bone marrow was studied and compared with that of a stimulant of antibody producers from the bone marrow of patients with acute myeloblastic leukemia, acute lymphoblastic leukemia, lymphosarcoma, and multiple myeloma. The activity of the SAP from human bone marrow in health was similar to that of analogous transmitters from the bone marrow of other species of the mammals and birds. The activity of the SAP in patients with multiple myeloma was elevated, whereas in patients with acute myeloblastic leukemia, it was lowered.     

Impulse cytophotometry studies of bone marrow and blood cells in children with acute lymphoblastic leukemia (ALL). 2. Lymphatic cells in blood

The DNA-content of mononuclear cells of the peripheral blood of infantile and juvenile ALL patients was investigated using Pulse Cytophotometry. The fraction of cells in S- and G2 + M-phase is significantly increased in comparison with samples of healthy probands. The fraction of DNA-synthesising cells (S-phase) of both peripheral blood (mononuclear cells) and bone marrow of leukemia patients cannot be significantly distinguished by mathematical methods. On the other hand, the fraction of cells in later phases of cell cycle (G2 + M-phase) is significant enhanced in the bone marrow in comparison with the peripheral blood. A high correlation was found between the number of leukocytes and fraction of G2 + M-phase cells in the peripheral blood of SR- and MR-patients. No correlation was found between the number of leukocytes and S-phase-fraction. The occurrence of aneuploid cell populations in the mononuclear fraction of peripheral blood in the acute state of ALL could be of importance for prognosis and regime of therapy.