Acute leukemia of ambiguous lineage with monosomy 7 and Philadelphia chromosome

A 67-year-old female was admitted with a diagnosis of acute leukemia. Immature blasts did not show cytoplasmic granules and were POX(-), ES(-), and PAS(+). Flow cytometry of leukemic cells demonstrated positivity for CD7, CD10, CD19, CD13, CD34, HLA-DR, and coexpression of CD7 and CD34, CD10 and HLA-DR, and CD19 and CD13. Cytogenetic analysis demonstrated -7 and t(9;22)(q34;q11.2), and genomic studies demonstrated minor BCR/ABL chimeric mRNA and rearrangements of IgH and TCR. These findings indicated the clonal proliferation of leukemic blasts that expressed a mixed phenotype. Acute leukemia of ambiguous lineage was diagnosed, although the significance of the specificity of lineage markers remains unclear. The differential diagnosis included CML and B-ALL. The patient was treated according to Ph+ALL. However, the hematological response was poor, with persistent residual blasts and severe pancytopenia. The subsequent administration of imatinib mesylate led to a complication of heart failure, and the patient died on the 19th hospital day.     

Growth of primary human acute leukemia in severe combined immunodeficient mice

Seven populations of human leukaemic cells were implanted i.v. into sublethally irradiated severe combined immunodeficient (scid) mice. Growth of leukaemia was monitored by labelling murine peripheral blood (PB) cells with an anti-HLA monoclonal antibody and flow cytometric analysis. Two of the populations transplanted were fresh acute lymphoblastic leukaemia (ALL) bone marrow (BM) cells which both caused sustained proliferative growth in scid mice. Human cells accounted for up to a mean of 87% of the total nucleated cells (TNC) in the PB of these mice between weeks 12-15. One of these populations was passaged into fresh mice and frank leukaemia was again established. Three populations of cryopreserved acute myeloblastic leukaemia (AML) cells (2 obtained from PB and 1 from BM) and one population of cryopreserved biphenotypic acute leukaemia BM cells, only grew to a maximum of 4% within the 15 week period of the experiment. A cell population from an AML cell line (HL60), however, did engraft and proliferate resulting in a rapid deterioration of these mice between weeks 3-6 when the proportion of human cells accounted for 9% of the TNC in the PB.     

Lineage switch in childhood acute leukemia: An unusual event with poor outcome

Although rarely, switches between lymphoid and myeloid lineages may occur during treatment of acute leukemias (AL). Correct diagnosis relies upon confirmation by immunophenotyping of the lineage conversion and certification that the same cytogenetic/molecular alterations remain despite the phenotypic changes. From a total of 1,482 AL pediatric patients, we report nine cases of lineage conversion (0.6%), seven from lymphoid (four Pro‐B, two Pre‐B, one Common) to myelo‐monocytic, and two from myeloid (bilineal, with myeloid predominance) to Pro‐B. Eight patients were infants. Switches were suggested by morphology and confirmed with a median of 15 days (range: 8 days‐6 months) from initiation of therapy. Of note, in five cases switches occurred before day 15. Stability of the clonal abnormalities was assessed by cytogenetic, RT‐PCR/Ig‐TCR rearrangement studies in all patients. Abnormalities in 11q23/MLL gene were detected in seven cases. Treatment schedules were ALL (two pts), Interfant‐99 (five pts) and AML (two pts) protocols. Despite changing chemotherapy according to the new lineage, all patients died. Our findings support the association of lineage switches with MLL gene alterations and the involvement of a common lymphoid B‐myeloid precursor. New therapies should be designed to address these rare cases. Possible mechanisms implicated are discussed. Am. J. Hematol., 2012. © 2012 Wiley Periodicals, Inc.     

An autopsy case of acute mixed lineage leukemia with monosomy 7 in a child

A five-year-old boy initially diagnosed common ALL was developed to acute myelomonocytic leukemia. At onset, the bone marrow was hypercellular and 77% of the cells were blasts, mainly lymphoblast-like cells and cytogenetic study demonstrated 45, XY, -7 in all blasts. Cytochemically most of those blasts were negative for peroxidase, sudan black B, alpha-NB esterase staining. The immunological phenotype was J5 (CD10)+, I2 (HLA-DR)+, SmIg-, CyIgmu-, Leu1 (CD5)-, OKT11 (CD2)-, MY7 (CD13)-, suggesting common ALL. Eight months later, the bone marrow cells were occupied with large sized blasts which were almost positive for peroxidase stain and the cells showed coexpression of Mo1 (CD11b)+, MY4 (CD14)+, MY7+, MY9 (CD33)+, MCS2 (CD13)+, I2+, J5-, B4 (CD19)-, Mo2 (CDw14)-, at relapse. He died 2 years and 6 months after his initial diagnosis. An autopsy was performed which revealed generalized infiltration of leukemic cells and aspergillosis of the lung. In general, monosomy 7 is associated with myelodysplastic syndrome in childhood, and is terminated to acute myeloblastic leukemia. In this case, bone marrow blasts demonstrated monosomy 7 cytogenetically, and this case was considered as an acute mixed lineage leukemia of bilineal type. And this case proved that a monosomy 7 can also be terminated to acute mixed lineage leukemia with both lymphoid and myeloid phenotypes.     

Interleukin-4 enhances the survival of severe combined immunodeficient mice engrafted with human B-cell precursor leukemia

Human interleukin-4 (huIL-4) has been shown to inhibit the growth in vitro of cells from patients with acute lymphoblastic leukemia (ALL). With the aim of determining whether this cytokine might be useful in the treatment of patients with ALL, the effects of huIL-4 on human B- cell precursor ALL engrafted in severe combined immunodeficient (SCID) mice were examined. The inhibition of [3H] thymidine uptake of primary ALL cells by huIL-4 was maintained following engraftment and passage of leukemia in SCID mice. Five of seven xenograft leukemias showed significant inhibition in vitro by huIL-4 at concentrations as low as 0.5 ng/mL; furthermore, huIL-4 counteracted the proliferative effects of IL-7. When used to treat two human leukemias engrafted in SCID mice, huIL-4 200 microgram/kg/d, as a continuous 14-day subcutaneous infusion, suppressed the appearance of circulating lymphoblasts and extended survival of mice by 39% and 108%, respectively, the first demonstration of IL-4 activity against human leukemia in vivo. The mean steady-state huIL-4 level in mouse plasma during the infusion was 1.46 ng/mL (SEM +/- 0.14 ng/mL), which was similar to concentrations found to be effective in vitro. ALL cells obtained from mice relapsing after huIL-4 treatment continued to show inhibition by the cytokine in vitro. These data suggest that IL-4 may be useful in the treatment of patients with ALL.     

Establishment of human T-cell leukemia virus type I T-cell lymphomas in severe combined immunodeficient mice

Human T-cell leukemia virus type I (HTLV-I) is recognized as the etiologic agent of adult T-cell leukemia (ATL), a disease endemic in certain regions of southeastern Japan, Africa, and the Caribbean basin. Although HTLV-I can immortalize T lymphocytes in culture, factors leading to tumor progression after HTLV-I infection remain elusive. Previous attempts to propagate the ATL tumor cells in animals have been unsuccessful. Severe combined immunodeficient (SCID) mice have previously been used to support the survival of human lymphoid cell populations when inoculated with human peripheral blood lymphocytes (PBL). SCID mice were injected intraperitoneally with PBL from patients diagnosed with ATL, HTLV-I-associated myelopathy/tropical spastic paraparesis (HAM/TSP), or from asymptomatic HTLV-I-seropositive patients. Many of these mice become persistently infected with HTLV-I. Furthermore, after human reconstitution was established in these mice, HTLV-I-infected cells displayed a proliferative advantage over uninfected human cells. Lymphoblastic lymphomas of human origin developed in animals injected with PBL from two ATL patients. The tumor cells represented outgrowth of the original ATL leukemic clone in that they had monoclonal or oligoclonal integrations of the HTLV-I provirus identical to the leukemic clone and predominantly expressed the cell surface markers, CD4 and CD25. In contrast, cell lines derived by HTLV immortalization of T cells in vitro did not persist or form tumors when inoculated into SCID mice, indicating differences between in vitro immortalized cells and ATL leukemic cells. This system represents the first small animal model to study HTLV-I tumorigenesis in vivo.     

Transformation of severe aplastic anemia into acute myeloblastic leukemia with monosomy 7

 A cytogenetically normal man with severe aplastic anemia was treated with granulocyte colony-stimulating factor (G-CSF), erythropoietin (EPO), cyclosporin A, anti-thymocyte globulin, and interleukin-6 (IL-6), which resulted in a gradual improvement in his neutrophil count and hemoglobin level. After 2 years of the therapy, monosomy 7 was detected during cytogenetic analysis of his bone marrow, which evolved during a period of 5 months into acute myeloblastic leukemia. An in vitro proliferation assay of cytokine responses showed that leukemic blasts were sensitive only to G-CSF, and not to EPO or IL-6. Although allogeneic bone marrow transplantation from an HLA-matched unrelated donor was carried out in the non-remission stage, the patient died of systemic fungal infection on day 25, without any evidence of hematological engraftment. As long-term use of cytokines and immunomosuppressants in patients with severe aplastic anemia may induce or hasten the onset of a malignant transformation, careful attention must be paid to clonal evolution. Due to the poor prognosis of secondary myelodysplasia and leukemia, allogeneic bone marrow transplantation for such patients must be carried out early in the course of the disease. Received: 27 September 1995 / Accepted: 19 December 1995     

Ring/marker chromosome derived from chromosome 7 in childhood acute megakaryoblastic leukemia with monosomy 7

In some cases of childhood acute megakaryoblastic leukemia (AMKL), G-band analysis reveals supernumerary ring/marker chromosomes along with monosomy 7. However, their origin and relevance are poorly understood. We experienced three patients with AMKL, one of whom had Down’s syndrome, whose blasts at the first visit exhibited both monosomy 7 and a ring/marker chromosome. For one case, precise molecular-cytogenetic techniques revealed that the ring chromosome was derived from a chromosome 7. It was strongly suggested that the ring chromosome was derived from a chromosome 7 in another case. The ring or one of the 2 marker chromosomes was derived from a chromosome 7 in the other case. All patients responded well to initial induction therapy. While it is not clear whether the ring/marker chromosome 7 affects the long-term prognosis of acute myeloid leukemia with monosomy 7, it may be of prognostic relevance to distinguish pure monosomy 7 from monosomy 7 with a ring/marker chromosome 7. For this purpose, conventional G-banding could be complemented with additional techniques such as spectral karyotyping or fluorescence in situ hybridization, which characterize the aberration in more detail. These methods may be useful for determining the optimal treatment and for elucidating the etiology of AMKL itself.     

Replication of human cytomegalovirus in severe combined immunodeficient mice implanted with human retinal tissue.

Because human cytomegalovirus (HCMV) infection and replication are limited to human cells, few animal models can be used to specifically examine the biology of HCMV in vivo. In these studies, fetal human retinal tissue was implanted into the anterior chamber of the severe combined immunodeficient (SCID) mouse eye and subsequently was inoculated with HCMV. Viral replication, localized to glial cells in the xenografts, was first detected 7 days after infection. Thereafter, HCMV replication increased to peak levels through days 21-28 and then gradually decreased to undetectable levels by 8 weeks after infection. The clinical isolate Toledo replicated to higher titers than did strain AD169 or Towne. A comparison of implant age indicated that older tissue could support higher levels of HCMV replication than could younger implants. SCID mice implanted with human retinal tissue provide an excellent model for evaluation of HCMV infection of an ocular structure in vivo.     

Epstein-Barr virus induced lymphoproliferative tumors in severe combined immunodeficient mice are oligoclonal.

Severe combined immunodeficient (SCID) mice reconstituted with lymphocytes from Epstein-Barr virus (EBV) negative human donors develop aggressive tumors after the chimeric mice are infected with EBV. The tumors were composed of human B cells that expressed EBV encoded antigens (latent membrane protein and EBV nuclear antigen2). Southern blot analysis of DNA from 16 SCID/hu tumors with human Ig gene probes showed that each tumor contained multiple heavy and light chain gene rearrangements. Ig kappa gene rearrangements were frequent, while clonal lambda gene rearrangements were infrequent. Analysis of EBV terminal repeat sequences indicated two or more fused termini in each tumor, consistent with a multiclonal origin. Linear terminal repeat segments and viral antigens (EA-D and EA-R) associated with EBV replication were not detected in the tumors. High levels of human Igs in the SCID/hu serum were oligoclonal and primarily contained kappa light chains. Before the appearance of overt tumors, circulating cells with human and EBV DNA could be detected in the SCID/hu mice by the polymerase chain reaction. We conclude that EBV infection in SCID/hu chimeric mice produces a limited number of transformation events, which give rise to oligoclonal tumors resembling EBV-associated lymphoproliferative disorders in some immune-deficient patients.     

Growth characteristics of acute myelogenous leukemia progenitors that initiate malignant hematopoiesis in nonobese diabetic/severe combined immunodeficient mice.

The use of immunodeficient mice, particularly of the nonobese diabetic/severe combined immunodeficient (NOD/SCID) strain, has allowed detection of very primitive malignant progenitors from patients with acute myelogenous leukemia (AML). To define the sensitivity and reproducibility with which the engraftment of different AML cells can be detected, 61 different samples from patients with newly diagnosed AML representing a variety of cytogenetic and French-American-British (FAB) subtypes were injected into NOD/SCID mice. Eight weeks after intravenous injection of 10(7) AML cells, the average percent of human cells in mouse bone marrow was 13.3%, with 70% of samples showing easily detectable engraftment of CD45(+) cells. AML samples with cytogenetic changes associated with a poor clinical prognosis tended to engraft to higher levels than those with changes associated with a good prognosis. Cells with FAB subtypes M3 and, to a lesser extent, M2, engrafted more poorly (P =.002 and.06, respectively) than those from other subtypes. Intraperitoneal injection of human interleukin-3 and Steel factor thrice weekly for 4 weeks did not enhance the levels of AML cell engraftment. However, AML samples that showed cytokine-independent colony growth in methylcellulose assay or expressed growth-factor mRNA in malignant blasts achieved significantly higher levels of engraftment than those which were cytokine dependent in culture or failed to express cytokine message (P <.03 and P <.02, respectively). In 6 patient samples, the frequency of NOD/SCID leukemia-initiating cells (NOD/SL-IC) varied from 0.7 to 45 per 10(7) cells, which was 200- to 800-fold lower than the frequency of AML long-term culture-initiating cells (AML LTC-IC) in the same samples. Each NOD/SL-IC will produce more than 10(6) leukemic blasts as well as many AML-CFC and AML LTC-IC as detected 8 weeks postinjection into mice. Serial transplant experiments showed the ability of NOD/SL-IC to maintain their own numbers over at least 3 to 4 weeks in vivo. The ability of these progenitors to self-renew combined with their potential to differentiate to produce large numbers of more mature progenitors and leukemic blasts suggests that the NOD/SL-IC assay identifies leukemic 'stem cells' that may maintain the malignant clone in human patients. The further use of this assay should facilitate studies of AML stem cell biology and the evolution of novel therapeutic strategies.     

A case of congenital leukemia with monosomy 7

Summary A case of congenital leukemia with monosomy 7 is reported. Immunological study of the blast cells using monoclonal antibodies was suggestive of both myelomegakaryocytic and T-lymphoblastic leukemia. Chromosomal analysis of the bone marrow cells showed monosomy 7. Chemotherapy was initiated with a combination of adriamycin, cytosine arabinoside, 6-mercaptopurine, and prednisolone. The patient obtained complete remission, which has been maintained for 4 years and 1 month. He receives no chemotherapy now. Our case shows that monosomy 7 in congenital leukemia is rare, but the presence of monosomy 7 in congenital leukemia does not necessarily indicate a poor prognosis.     

Adoptive transfer of immunity with intraepithelial lymphocytes in Cryptosporidium parvum-infected severe combined immunodeficient mice

BACKGROUND: Intestinal infections with the protozoan parasite Cryptosporidium parvum are prevalent in both immunocompetent and immunocompromised hosts. Although C parvum is an important cause of outbreaks and opportunistic infections worldwide, little is known about protective mucosal immune responses. This is in part because animal models of infection are limited to those with genetic or induced immunodeficiencies. METHOD: In this report, we isolated immune (primed) or nonimmune (unprimed) intraepithelial lymphocytes (IEL) from BALB/cJ mouse intestines, adoptively transferred them into C parvum-infected severe combined immunodeficient (SCID) mice, and evaluated infection and cell phenotype responses. RESULTS: Control SCID mice that received no IEL shed large numbers of oocysts throughout the experimental period (day 18 to day 72). Transfer of primed IEL significantly reduced fecal oocyst shedding in recipient SCID mice compared with SCID mice that received unprimed IEL or no IEL. SCID mice transferred with unprimed IEL shed variable numbers of fecal oocysts that increased and decreased in bursts until day 57 after infection. SCID mice transferred with primed IEL exhibited significantly higher proportions of T-cell receptor (TCR) alphabeta+, CD8+, and CD8alphabeta+ EL compared with inoculated SCID mice that received unprimed or no IEL. CONCLUSION: We conclude that primed IEL from immunocompetent mice may influence protective mucosal response against cryptosporidiosis when transferred into SCID mice. In addition, the increased percentage of TCR alphabeta+, CD8+, CD8alphabeta+ IEL in recipient SCID mice may reflect mucosal cell populations involved in these responses during chronic C parvum infection.     

Familial leukemia and aplastic anemia associated with monosomy 7

A kindred is described in which eight of 14 patients in one generation had acute nonlymphocytic leukemia or aplastic anemia either alone or terminating in acute nonlymphocytic leukemia. The proband and two siblings in one branch of this kindred presented with aplastic anemia, whereas acute nonlymphocytic leukemia was the presenting feature in the other two branches. Karyotypic evolution from a normal karyotype to monosomy 7 was demonstrated in the proband, and group C monosomy was seen in two other patients. The proband's serum sample inhibited in vitro growth of normal bone marrow colonies. The occurrence of hematologic disease in this kindred appears to be the result of a maternally transmitted trait, and persons younger than 30 years of age appear to have the highest risk of hematologic disease.     

Childhood acute myeloid leukemia in mice with severe combined immunodeficiency

Primary bone marrow blasts from 4 children with t(8;21) acute myeloid leukemia (AML), 6 children with inv(16) AML, and 2 children with t(9;11) AML were injected intravenously or transplanted under the kidney capsule of sublethally irradiated mice with severe combined immunodeficiency (SCID). Leukemic cells from all AML patients infiltrated the SCID mouse thymus, suggesting that the thymic microenvironment supports the survival and growth of human AML blasts. Blasts from 1 of 4 t(8;21) AML patients and 4 of 6 inv(16) AML patients caused histopathologically detectable disseminated leukemia. Blasts from the remaining patients produced disseminated occult leukemia that was only detected by polymerase chain reaction. Occurrence of histopathologically detectable disseminated leukemia was dependent on intravenous injection of leukemic cells; none of the mice challenged with an inoculum transplanted under the kidney capsule developed overt leukemia. No obvious association was noted between occurrence of leukemia in SCID mice and clinical or laboratory features presented by patients, including age, sex, or leukocyte count at diagnosis. To our knowledge, this study is the first to show that leukemic blasts from children with newly diagnosed AML, especially inv(16) AML, can cause disseminated human leukemia in SCID mice without exogenous cytokine support. The SCID mouse model system may prove particularly useful for designing more effective treatment strategies against childhood AML.     

Antibody-targeted lymphokine-activated killer cells inhibit liver micrometastases in severe combined immunodeficient mice

Animal models for hepatic metastases can facilitate the investigation of lymphokine-activated killer (LAK) cell-based immunotherapy. The aim of this study was to investigate the efficacy of ccM4 antibody-targeted LAK cells in inhibiting hepatic micrometastases. Hepatic micrometastases were generated after the intrasplenic injection of HM7 colon carcinoma cells. TAG72 expression was detected in these hepatic micrometastases using ccM4 antibody. The ccM4 antibody was conjugated onto LAK cells by treatment with 17.5% polyethylene glycol 8000. After the intrasplenic injection of HM7 cells, severe combined immunodeficient mice were randomized into five groups (i–v) and received either 10⁷ ccM4-LAK cells plus 1000 U interleukin 2 (IL-2; group i), LAK cells plus 50 μg ccM4 and IL-2 (group ii), LAK cells plus IL-2 (group iii), IL-2 alone (group iv), or only phosphate-buffered saline (group v). The ccM4-LAK cells retained cytolytic activity and acquired TAG72-binding reactivity. The results showed that group i had significantly fewer hepatic metastases compared with group ii or group iii (P < 0.05) and even fewer hepatic metastases compared with group iv or group v (P < 0.001). These results show that ccM4 antibody-targeted LAK cells significantly inhibited tumor growth in vivo; thus, they can be potentially useful in treatment of hepatic micrometastases.     

Preconditioning with fetal cord blood facilitates engraftment of primary childhood T-cell acute lymphoblastic leukemia in immunodeficient mice

Childhood T-cell acute lymphoblastic leukemia (T-ALL) is one of the most common childhood cancers. It is reported that preconditioning sublethally irradiated immunodeficient NOD/SCID (nonobese diabetic/X-linked severe combined immunodeficient) mice with human cord blood mononuclear cells facilitates the engraftment, expansion, and dissemination in these mice of primary T-ALL cells obtained from patients at the time of diagnosis. Cells recovered from mouse bone marrow or spleen resembled the original leukemia cells from patients with respect to surface lineage markers and T-cell receptor Vbeta gene rearrangements. Moreover, the pattern of leukemia dissemination in mouse tissues, resulting in universally fatal leukemia, is reminiscent of the human clinical disease. In addition, the fidelity of the model to the human disease is documented with regard to the presence of morphologically identifiable human leukemia cells in mouse bone marrow and blood and the maintenance of leukemia-initiating capacity within the leukemia-engrafted mouse. Therefore, several lines of independent approaches are used to suggest that the engrafted cells are of human leukemia origin and are not derived from cord blood. The in vivo model described here should enable the study of the growth properties of primary T-ALL cells obtained from patients and should prove useful in evaluating the potential efficacy of therapeutic strategies directed toward T-ALL.     

Philadelphia chromosome and monosomy 7 in childhood acute lymphoblastic leukemia: a Pediatric Oncology Group study

During an 8-year period, 3,638 children from institutions of the Pediatric Oncology Group (POG) were diagnosed with acute lymphoblastic leukemia (ALL). Fifty-seven patients had Philadelphia chromosome-positive (Ph1) ALL. Blast cells obtained at diagnosis from 13 of these 57 cases (23%) were also found to have partial or complete monosomy 7 (-7). This subgroup of children with Ph1/-7 ALL was comprised primarily of older males with early B-lineage ALL. Bone marrow specimens from six Ph1/-7 patients were studied further using the polymerase chain reaction and primers that flank the ALL, and chronic myelogenous leukemia breakpoints to determine the molecular characteristic of the 9;22 translocation. Rearrangements were detected in RNA from bone marrow and/or peripheral blood cells of six patients, although four were in hematologic remission at the time of the analysis. Five cases showed the ALL breakpoint, while one child with Ph1/-7 showed the chronic myelogenous leukemia breakpoint. The induction failure rate was much higher in this subgroup (31%) as compared with Ph1-negative cases, and the projected duration of event-free survival reflected the aggressive nature of this subgroup because no children are projected to remain in remission at 2 years. ALL with both the 9;22 translocation and -7 appears to represent a unique and previously undescribed subgroup of childhood ALL associated with a particularly adverse outcome. Leukemic transformation in such patients may involve the interaction of a dominant oncogene (Ph1) and a tumor suppressor gene (-7).