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Query: UMLS:C0026764 (multiple myeloma)
 36,148 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The last decade has seen major advances in the acquisition of knowledge concerning both the cellular and molecular genetics of multiple myeloma. Although discrete and specific changes associated with the plasma cell disorders have yet to be identified, a pattern is emerging that one can associate with the plasma cell disorders. This pattern includes the frequent involvement of chromosomes 1 and 14, and in particular presence of the 14q+ abnormality. But in addition there are typically many other numeric and/or structural changes that can, in fact, involve almost any chromosome, but particularly chromosomes 3, 5, 6, and 7, as well as 11, 14, 17, and 18. The presence of one or more unidentified marker chromosomes is also a typical feature. The ongoing challenges include identification of a crucial initial genetic change (if such exists) as well as the factors contributing to the ongoing karyotypic evaluation that results in complex karyotypes in patients with advanced disease. There is no doubt that the complex karyotypic picture contributes to the major heterogeneity of plasma cells that occurs in malignant plasma cell disorders. Karyotypic complexity underlies heterogeneity in cell morphology, surface antigen expression, response to cytokines, and a variety of other functional characteristics. The aberrant expression of antigens normally found on other hematopoietic progenitors has led to speculation about the true nature of the stem cell in myeloma. The overriding challenge, however, is to fully understand the plasma cell disorders at the molecular level. Although changes have already been noted in the functions of C-myc, the ras family of oncogenes, Bcl-2 expression, and several so called anti-oncogenes such as p53, it is likely that we have only begun to scratch the surface in the area of molecular changes. The potential for involvement at multiple molecular sites and the possibility of complex interactions between gene segments is truly overwhelming. However, it is hoped that at the molecular level a pattern will ultimately emerge. It is most interesting, as previously discussed, that there is an interplay among C-myc, N-ras, Bcl-2, and the Epstein-Barr virus in the predilection for a plasma cell phenotype. Undoubtedly there is much more to learn, and it is truly exciting to finally have some tools and probes at hand to more effectively study the genome in multiple myeloma and related disorders.
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PMID:Cellular and molecular genetic features of myeloma and related disorders. 158 85

Multiple myeloma (MM) originates from the malignant clonal expansion of transformed B-lymphocytes (in which c-myc and ras oncogenes are probably involved). MM cells have a hybrid phenotype (with coexpression of the markers for both early and late B-differentiation and, sometimes, of T-lymphocyte, myelomonocyte, erythroid and megakaryocyte markers), which accounts for the association between MM and myeloproliferative disorders and for cytokine production. Interleukin-6 and immunologic control mechanisms regulate proliferation and differentiation into plasma cells secreting a monoclonal component (MC). Overt MM is diagnosed 1-2 years following malignant transformation. At this time, several aneuploid clones with resistant phenotype have been selected, and a small pool of actively cycling cells produces the great bulk (over 90%) of non proliferating tumor cells. The clinical and laboratory signs of MM arise from both tumor proliferation and MC damage to organs and organ systems. Tumor proliferation is mainly responsible for bone disease (since MM cells produce cytokines that activate the osteoclasts), inhibition of hemopoiesis and the appearance of plasma cell tumors. The MC causes renal failure, neurological signs, hemorrhagic manifestations. The prognosis for multiple myeloma is probably best estimated by two parameters, serum beta-2-microglobulin and the bone marrow labeling index. Induction therapy is still based on the use of alkylating agents, melphalan and cyclophosphamide, combined with prednisone. Second line treatment consists of VAD polychemotherapy or high-dose pulsed glucocorticoids. Many investigational approaches have been proposed, but their effectiveness awaits confirmation. In the absence of a curative regimen, much effort should be dedicated to the quality of supportive care. In this respect, bisphosphonates represent a new effective tool for the control of myeloma bone disease.
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PMID:Multiple myeloma. 208 Oct 91

Flow cytometry (FCM) is a useful method for clinical research of oncogene products since it can analyze proteins quantitatively which are located at cell surfaces or inside of cells. Oncogene products are now under study by FCM not only as tumor markers but also as functioning proteins in carcinogenesis. The examples of oncogene products analyzed by FCM are ras, myc, p53, myb and fos; those of cell-proliferation-related proteins are Ki-67, PCNA and DNA polymerase alpha. In some diseases the relationship between these proteins and disease classification, stage, pathophysiology, or prognosis have been clarified. Using dual color FCM of H-ras p21 and DNA, we analyzed the expression of H-ras p21 in human multiple myeloma and leukemias and found that H-ras p21 levels in multiple myeloma strongly correlated to the prognosis of patients (p = 0.03). When AML cells were stimulated by adding G-CSF, it was found that many cells proliferated but some were dying. The percentage of dying cells was small in one AML case whose myeloblasts showed increased expression of H-ras p21 by G-CSF stimulation. Together with other papers reviewed, it is conceivable that H-ras p21 expression is related to cell proliferation and inhibition of cell autolysis. Thus FCM is useful in the classification of the role of oncogene products in carcinogenesis in clinical cases.
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PMID:[Application of flow cytometry to the study of hematologic disorders: analysis of oncogene products]. 214 49

Using bivariate flow cytofluorometry, we have determined the nuclear DNA distribution and the expression of the p21 protein (coded by the Ha-ras oncogene) in the bone marrow (BM) cells of five solid tumour patients having histologically normal BM and in those of 57 patients with plasma cell dyscrasia (28 with monoclonal gammopathies of undertermined significance, MGUS, and 29 with multiple myeloma, MM). All normal and MGUS and 21/29 (72.4%) MM BM had diploid modal DNA content and 8/29 (27.6%) MM BM had both diploid and hyperdiploid cell populations. In normal and MGUS BM, the level of the p21 oncoprotein was low and uniform in all G0/G1, S and G2 cells (median fluorescence values in arbitrary units were 6.1 and 7.5, respectively). The level of p21 was increased both in different aliquots of G0/G1 cells and in the S and G2 cells in diploid MM (median value for G0/G1 cells was 20), and especially in MM with hyperdiploid clones (median value for hyperdiploid cells was 40.5, P less than 0.005 with respect to normal and MGUS BM and less than 0.005 with respect to diploid MM BM). The p21 expression was greater in patients with advanced (stage III) than in earlier MM (stages I + II) (P less than 0.005), and it was directly related to the BMPC infiltration (r = 0.7; P less than 0.005). Since p21 expression is greater in MM than in both normal and MGUS BM, Ha-ras could be involved in the malignant plasma cell transformation that distinguishes MM from MGUS.
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PMID:Ras oncogene expression and DNA content in plasma cell dyscrasias: a flow cytofluorimetric study. 224 70

Alterations of ras, c-myc and bcl-1 have been described in hematologic malignancies of lymphoid origin. We investigated the structure of these genes and evaluated the frequency of point mutations involving H-, K- or N-ras in bone marrow samples from patients with multiple myeloma. No abnormalities were detected in the c-myc and bcl-1 genes, but two of 17 patients were found to have N-ras mutations by differential oligonucleotide hybridization and dideoxynucleotide sequencing following amplification by polymerase chain reaction. Bone marrow DNA from both patients had identical missense mutations of N-ras codon 61 changing CAA to AAA, resulting in a substitution of lysine for glutamine in the encoded protein. Multiple myeloma is the first mature B cell neoplasm found to harbor ras mutations.
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PMID:Oncogenes in multiple myeloma: point mutation of N-ras. 226 33

The biological effects of ras oncogene activation in B cells were studied by using amphotropic retroviral vectors to introduce H- or N-ras oncogenes into human B lymphoblasts immortalized by Epstein-Barr virus. Expression of both H- and N-ras oncogenes led to malignant transformation of these cells, as shown by clonogenicity in semisolid media and tumorigenicity in immunodeficient mice. In addition, terminal differentiation into plasma cells was detectable as specific changes in morphology, immunoglobulin secretion, and cell surface antigen expression. This combined effect, promoting growth and differentiation in human lymphoblasts, represents a novel biological action of ras oncogenes and has implications for the pathogenesis of terminally differentiated B-lymphoid malignancies such as multiple myeloma.
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PMID:Transformation and plasmacytoid differentiation of EBV-infected human B lymphoblasts by ras oncogenes. 253 54

The frequency of ras (H-, K-, and N-ras) and c-myc oncogenes was investigated in multiple myeloma (MM). By means of the polymerase chain reaction (PCR)/oligonucleotide hybridization method, DNA from 56 tumor biopsies was analyzed for the presence of activating mutations involving codons 12 and 61 of the H-, K-, and N-ras genes and codon 13 of the N-ras gene. Mutations, involving the N- or K-ras genes, were detected in 18 of 56 (32%) cases of which 12/43 (27%) were at diagnosis and 6/13 (46%) were after treatment. In some cases, multiple mutations affecting different ras alleles were detected. Direct nucleotide sequence analysis of PCR products indicated that a more heterogeneous nature of the base pair changes than previously shown for other tumors along with a preferential involvement of N-ras codon 61. The heterogeneity of MM cases with respect to the presence of ras oncogenes prompted an analysis of possible correlations with different clinico-pathologic characteristics of MM from which a correlation between the presence of ras oncogenes and a partial or complete lack of response to therapy emerged. The frequency of activating rearrangements or mutations of the c-myc gene were studied by Southern blot analysis and PCR sequencing, respectively. However, contrary to previous reports involving mostly MM cell lines, no structural alterations of the c-myc gene were found. These results indicate that ras, but not c-myc, oncogenes are activated in vivo in MM cells, representing the first oncogene alteration that has been associated at appreciable frequency with this type of malignancy. While the mechanism of occurrence and biological role of ras activation in MM remains to be elucidated, the preliminary correlations observed in this study between the presence of ras oncogenes and poor therapeutic response suggest that further investigations of the possible prognostic significance of these alterations are necessary.
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PMID:Ras oncogene mutation in multiple myeloma. 268 17

Bone marrow plasma cell proliferative activity has been evaluated in a large series of multiple myeloma (MM) patients. This kinetic parameter has been shown to be a useful tool for patient management, and contributes to a correct diagnosis and a selection of high-risk patients who can be offered high-dose chemotherapy. The role of ras oncogenes has been evaluated in the pathogenesis of MM. A point-mutated and activated H-ras oncogene, introduced in a human lymphoblastoid cell line, was able to induce neoplastic transformation and differentiation to plasma cell. Indeed, mutated alleles of ras genes have been detected in a high percentage of myeloma patients in relapse phase. Phenotypical and functional studies have been carried out in T-lymphocyte subsets and an impaired cellular immunity has been detected. Such an impairment was related to the disease status: marked alterations were detected in relapse phase, whereas a partial recovery was observed during remission phase.
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PMID:Advances in biology of multiple myeloma: cell kinetics, molecular biology and immunology. 269 92

Using the human liver cancer DNA transfected NIH/3T3 cell line, the human N-ras oncogene and the over expression of the oncoprotein P21ras was demonstrated, BALB/C mice were immunized. The spleen cells from the immunized mice were fused with SP2/0 myeloma cells. After the HAT medium selection and screening, two hybridoma cell lines, SCI-Oncogema 1 and 2, were established. In the immunoprecipitation test, the molecular weight of the protein reacting to Oncogema 1 was 21,000. This M.W 21,000 protein possessed the capability to bind with GTP, i.e. the character of P21ras. These data indicate that the Oncogema 1 is the monoclonal antibody against P21ras. Using Oncogema 1, specimens from 6 liver cancer patients were studied by immunopathology. With ABC stain, it was observed that the malignant cells in all the samples showed dark staining; the P21ras revealed over expression. Although the staining was heterogeneous, it implied that the ras oncogene was involved in the carcinogenesis of these six samples. No over expression was seen in the normal liver cells even in those around the cancerous lesion. However, dysplastic cells were moderately stained which means that the ras oncogene was activated and P21ras over expressed in these cells. The results suggest that the ras oncogene and P21ras play an important role in the early stage of liver cancer carcinogenesis.
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PMID:[Localization of oncoprotein P21ras in the human liver cancer]. 330 83

We have isolated eight rat lymphocyte-myeloma hybrid cell lines producing monoclonal antibodies that react with the 21,000-dalton transforming protein (p21) encoded by the v-ras gene of Harvey murine sarcoma virus (Ha-MuSV). These antibodies specifically immunoprecipitate both phosphorylated and non-phosphorylated forms of p21 from lysates of cells transformed by Ha-MuSV. All eight react with the products of closely related ras genes expressed in cells transformed by two additional sarcoma viruses (rat sarcoma virus and BALB sarcoma virus) or by a cellular Harvey-ras gene placed under the control of a viral promoter. Three of the antibodies also react strongly with the p21 encoded by the v-ras gene of Kirsten MuSV. These same three antibodies immunoprecipitate the predominant p21 species synthesized normally in a variety of rodent cell lines, including the p21 produced at high levels in 416B murine hemopoietic cells. This suggests that an endogenous gene closely related to Kirsten-ras is expressed in these cells. The monoclonal antibodies have been used to confirm two properties associated with p21; localization at the inner surface of the membrane of Ha-MuSV-transformed cells, assayed by immunofluorescence microscopy, and binding of guanine nucleotides.
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PMID:Monoclonal antibodies to the p21 products of the transforming gene of Harvey murine sarcoma virus and of the cellular ras gene family. 628 3


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