Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Bovine leukemia virus (BLV) and the human T-cell leukemia virus types I and II comprise a unique retrovirus subfamily which has evolved complex strategies for the regulation of gene expression. A transcriptional control circuit has been characterized in both human and bovine systems in which cis-acting promoter control elements are responsive to trans-acting factors encoded in the pX region of the virus. The BLV pX mRNA encoding the transcriptional trans-acting factor is translated in an alternate reading frame to produce an 18-kilodalton nuclear phosphoprotein, p18. A function for this protein was revealed in cotransfection experiments using mutated BLV proviruses in combination with pX expression plasmids. These experiments indicated that p18 was required for the accumulation of viral mRNAs representing full-length (genomic) and single-spliced (env) transcripts. In contrast, synthesis of the double-spliced pX mRNA was not influenced by p18 expression. Large regional deletions and substitutions of provirus sequences localized elements essential for p18 regulation to the 3' long terminal repeat. Furthermore, sequences within a 250-nucleotide region between the AATAAA signal and poly(A) site were found to be essential for efficient virus mRNA 3'-end processing and response to p18 regulation.
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PMID:trans-acting regulation of bovine leukemia virus mRNA processing. 283 74

Bovine leukemia virus (BLV) is the causative agent of enzootic bovine lymphosarcoma. Much speculation continues to be directed at the role of BLV in human leukemia. To test this hypothesis rigorously, a case-control study of childhood acute lymphoblastic leukemia and non-Hodgkin's lymphoma was conducted between December 1983 and February 1986. Cases (less than or equal to 16 years at diagnosis) derived from patients diagnosed at the primary institutions and affiliated hospitals were matched (age, sex, and race) with regional population controls. DNA samples from bone marrow or peripheral blood from 157 cases (131 acute lymphoblastic leukemia, 26 non-Hodgkin's lymphoma) and peripheral blood from 136 controls were analyzed by Southern blot technique, under highly stringent conditions, using cloned BLV DNA as a probe. None of the 157 case or 136 control DNA samples hybridized with the probe. The high statistical power and specificity of this study provide the best evidence to date that genomic integration of BLV is not a factor in childhood acute lymphoblastic leukemia/non-Hodgkin's lymphoma.
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PMID:No involvement of bovine leukemia virus in childhood acute lymphoblastic leukemia and non-Hodgkin's lymphoma. 283 51

Twenty-four, six month old lambs were assembled into four groups of five animals each and one group of four animals. All groups were inoculated with lymphocytes from a single donor lamb infected with bovine leukemia virus. The inoculum varied from 250 to 250,000 lymphocytes, in tenfold increments. Animals were exposed by intradermal injection in the neck region immediately anterior to the left shoulder joint. All groups were monitored at 0, 3, 7 and 12 weeks after inoculation using the following procedures: a. Syncytia induction assay for detection of bovine leukemia virus in peripheral blood lymphocytes. b. Agar gel immunodiffusion against the gp51 antigen of bovine leukemia virus for the detection of antibovine leukemia virus gp51 antibody. c. Lymphocyte stimulation test for the assessment of cell-mediated immunity using mitogen, nonfractionated bovine leukemia virus antigen, and partially purified bovine lymphoma tumor-associated antigen for the in vitro activation of lymphocytes from bovine leukemia virus-inoculated and sham-inoculated, control animals. d. Routine hematological techniques for the assessment of total leukocyte and lymphocyte counts. The median infectious dose for lymphocytes from the single bovine leukemia virus-infected donor used in this study was determined to be 2000 cells. The syncytia induction assay detected more infected individuals (13/23) at an earlier time than did the agar gel immunodiffusion assay (10/23). Using either serological or virus isolation techniques, infected animals were first detected at three weeks postinoculation in the group receiving the high-dose inoculum and at seven weeks postinoculation in groups receiving low- or medium-dose inocula.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The role of virus dose in experimental bovine leukemia virus infection in sheep. 283 45

Bovine leukemia virus (BLV) replication in B lymphocytes from experimentally infected sheep depends on three conditions. First, viral production is detected only when the infected animals exhibit blood lymphocytosis. Second, it requires in vitro cultivation but is never observed in vivo. Third, enhancement of virus expression after phytohemaglutinin (PHA) or concavalin A stimulation is observed in lymphocyte cultures for all infected animals, whereas specifically B cell mitogens are inefficient. The PHA effect is linked to the presence of T lymphocytes. In addition, the conditioned medium prepared from PHA-stimulated normal lymphocytes greatly enhances BLV production. Altogether, these results establish that T lymphocytes, through a lymphokine production, are important and may be essential for BLV growth in B lymphocytes.
Leukemia 1988 May
PMID:T-B cell cooperation for bovine leukemia virus expression in ovine lymphocytes. 283 67

Bovine leukaemia virus (BLV) is the etiological agent of chronic lymphatic leukaemia/lymphoma in cows, sheep and goats. Infection without neoplastic transformation was also obtained in pigs, rhesus monkeys, chimpanzees, rabbits and observed in capybaras and water-buffaloes. Structurally and functionally, BLV is a relative of human T lymphotropic viruses 1 and 2 (HTLV-I and HTLV-II) In humans, HTLV-I induces a T-cell leukaemia and its type 2 counterpart has been found in dermatopathic lymphadenopathy, hairy T-cell leukaemia and prolymphocytic leukaemia cases. At variance with HTLV-I, BLV has not been associated with neurological diseases of the degenerative type. Bovine leukaemia virus, HTLV-I and HTLV-II show clearcut sequence homologies. The pathology of the BLV-induced disease, most notably the absence of chronic viraemia, a long latency period and lack of preferred proviral integration sites in tumours, is similar to that of adult T-cell leukaemia/lymphoma induced by HTLV-I. The most striking feature of these three naturally transmitted leukaemia viruses is the X region located between the env gene and the long terminal repeat (LTR) sequence. The X region contains several overlapping long open reading frames. One of them, designated XBL-I, encodes a trans-activator function capable of increasing the level of gene expression directed by BLV-LTR and most probably is involved in "genetic instability" of BLV-infected cells of the B cell lineage. The "genetic instability" renders the infected cell susceptible to move, along a number of stages, towards full malignancy. Little is known about these events and their causes; we present some theoretical possibilities. Bovine leukaemia virus infection has a worldwide distribution. In temperate climates, the virus spreads mostly via iatrogenic transfer of infected lymphocytes. In warm climates and in areas heavily populated by haematophagous insects, there are indications of insect-borne propagation of the virus.
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PMID:Bovine leukaemia: facts and hypotheses derived from the study of an infectious cancer. 284 91

Bovine leukemia virus is the etiological agent of a chronic lymphatic leukemia/lymphoma in cows, sheep, and goats. Infection without neoplastic transformation also was obtained in pigs, rhesus monkeys, chimpanzees, and rabbits, and was observed in capybaras and water buffaloes. Structurally and functionally, BLV is a relative of the human T lymphotropic viruses (HTLV-I and HTLV-II). HTLV-I induces in humans a T cell leukemia, and its type II counterpart has been found in dermatopathic lymphadenopathy, hairy T cell leukemia and prolymphocytic leukemia cases. At variance with HTLV-I, BLV has not been associated with neurological diseases of the degenerative type. BLV, HTLV-I, and HTLV-II show clearcut sequence homologies. The pathology of the BLV-induced disease, most notably, the absence of chronic viremia, a long latency period, and a lack of preferred proviral integration sites in tumors, is similar to that of adult T cell leukemia/lymphoma induced by HTLV-I. The most striking feature of the three naturally transmitted leukemia viruses is the X region located between the env gene and the LTR sequence. The X region contains several overlapping long open reading frames. One of them designated XBL-I encodes a trans-activator function capable of increasing the level of gene expression directed by BLV-LTR and most probably involved in "genetic instability" of BLV-infected cells of the B cell lineage. The genetic instability puts the cell into a context of fragility and ready to move along a number of stages towards full malignancy. Little is known about these events and their causes; we have presented some theoretical possibilities. BLV infection has a worldwide distribution. In temperate climates the virus spreads mostly via iatrogenic transfer of infected lymphocytes. In warm climates and in areas heavily populated by hematophageous insects, there are indications of insect-born propagation of the virus.
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PMID:Bovine leukemia: facts and hypotheses derived from the study of an infectious cancer. 284 1

For detection of antibody to bovine leukemia virus (BLV) major core protein of p24 and cross-reactive antibody in human patients infected with human T cell leukemia virus type I (HTLV-I), monoclonal antibody, D432 against BLV p24 was used by competitive binding enzyme-linked immunoadsorbed assay (ELISA). In sera from cattle with enzootic bovine leukosis (EBL) which were positive for BLV antibodies by immunodiffusion test, 109 out of 112 (97.3%) were positive for BLV p24 antibody by competitive binding ELISA. By using the same procedures, 21 samples from adult T cell leukemia (ATL) patients and healthy carriers with HTLV-I were tested for cross-reactive antibody to BLV p24. All 21 samples were positive for HTLV-I antibodies by immunofluorescence test and/or ELISA. By competitive binding ELISA using non-treated BLV antigens, none of these 21 samples inhibited the binding of the D432. When the BLV antigen was treated by several different denaturation procedures, several HTLV-I positive samples showed the inhibition of the D432 binding and the most effective treatment was by 2-mercaptoethanol (2-ME). Sixteen out of 21 samples showed the presence of cross-reactive antibody against 2-ME-treated BLV antigens. The cross-reactivity of human sample to BLV p24 antigen was further confirmed by Western blotting of the 2-ME-treated BLV antigens. None of the 28 samples from leukemia patients other than ATL which were negative for HTLV-I antibodies showed inhibition of the D432 by the competitive binding ELISA.
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PMID:Detection of cross-reactive antibody to BLV p24 in sera of human patients infected with HTLV. 288 27

Bovine leukaemia virus (BLV) is the aetiological agent of a chronic lymphatic leukaemia/lymphoma in cows, sheep and goats. Infection without neoplastic transformation has also been demonstrated in pigs, rhesus monkeys, chimpanzees and rabbits and observed in capybaras and water buffaloes. Structurally and functionally, BLV is a relative of human T lymphotropic viruses 1 and 2 (HTLV-I and HTLV-II) since all three viruses show clear-cut sequence homologies. The pathology of the BLV-induced disease, most notably the absence of chronic viraemia, a long latency period and lack of preferred proviral integration sites in tumours, is similar to that of adult T-cell leukaemia/lymphoma induced by HTLV-I. The most striking feature of the three naturally transmitted leukaemia viruses is the X region located between the env gene and the long terminal repeat (LTR) sequence. The X region contains several overlapping long open reading frames, one of which, designated XBL-1, encodes a trans-activator function capable of increasing the level of gene expression directed by BLV-LTR and is most probably involved in genetic instability of BLV-infected cells of the B-cell lineage. The 'genetic instability' may put the cell into a state of fragility, ready to move along a number of stages towards full malignancy. Little is known about these events and their causes and we present some theoretical possibilities. BLV infection has a worldwide distribution. In temperate climates the virus spreads mostly through iatrogenic transfer of infected lymphocytes. In warm climates and in areas heavily populated by haematophagous insects, there are indications of insect-borne propagation of the virus.
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PMID:Bovine leukaemia: facts and hypotheses derived from the study of an infectious cancer. 289 39

Human T-cell leukemia virus type III (HTLV-III) was recently identified as the probable etiologic agent of the acquired immune deficiency syndrome (AIDS). Here it is shown that, in human T-cell lines infected with HTLV-III, gene expression directed by the long terminal repeat sequence of this virus is stimulated by more than two orders of magnitude compared to matched uninfected cells. The rate of transcription of the HTLV-III long terminal repeat is more than 1000 times that of the SV40 early promoter in one infected cell line. Thus, HTLV-III, like HTLV-I, HTLV-II, and the bovine leukemia virus, is characterized by trans-activation of transcription in infected cells. The efficiency of trans-activation in the case of HTLV-III may account, at least in part, for the virulent nature of HTLV-III infection.
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PMID:Trans-acting transcriptional regulation of human T-cell leukemia virus type III long terminal repeat. 298 27

The transcription initiation signals for retroviruses lie within the long terminal repeat (LTR) sequences that flank the integrated provirus. This study shows that factors present in cells infected with bovine leukemia virus (BLV) mediate transcriptional trans activation of the BLV LTR. This phenomenon is similar to that reported for the human T-cell leukemia virus LTR and establishes both structural and functional criteria for inclusion of BLV and human T-cell leukemia viruses in the same family of transforming retroviruses.
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PMID:Trans activation of the bovine leukemia virus long terminal repeat in BLV-infected cells. 298 32


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