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Effects of soy isoflavones on breast tumorigensis in MMTV-NEU transgenic miceJin, Zeming, January 2003 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2003. / Typescript. Vita. Includes bibliographical references (leaves 126-148). Also available on the Internet.
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Effects of soy isoflavones on breast tumorigensis in MMTV-NEU transgenic mice /Jin, Zeming, January 2003 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 2003. / Typescript. Vita. Includes bibliographical references (leaves 126-148). Also available on the Internet.
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Host resistance and viral transcription as determinants of MMTV tumorigenesisBhadra, Sanchita 28 August 2008 (has links)
Not available / text
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CDP/Cutl1 controls differentiation-specific MMTV and cellular gene expression in the mammary glandMaitra, Urmila 28 August 2008 (has links)
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Characterization of the MMTV-encoded Rem proteinAli, Almas Fatima, 1986- 01 November 2010 (has links)
Mouse mammary tumor virus (MMTV) is a betaretrovirus that causes mammary tumors in mice. MMTV is the only known complex murine retrovirus and encodes Rem, an HIV-1 Rev-like protein. Rem is a 301-amino-acid (33 kDa) protein that is cotranslationally targeted to the ER, where the first 98 amino acids constitute the signal peptide (SP). The SP is cleaved and retrotranslocated to the cytoplasm prior to nuclear entry. In this thesis, the results show that the presence of a leucine at position 71 allows more efficient cleavage of SP and increases Rem activity. Further, in Rem-transfected cells, the majority of SP appears in the nuclear fraction, consistent with fluorescent microscopy data. The C-terminal fragment of Rem (RemCT) is glycosylated in the ER and, although glycosylation sites are present outside the SP, mutations of both these sites abolish SP activity in a reporter assay. Indirect evidence suggests that unglycosylated RemCT is degraded by the proteasome, whereas glycosylated RemCT is likely secreted out of the cell. A variant of MMTV (TBLV) that lacks functional Sag and RemCT has been prepared and will be studied in mice to elucidate the role of RemCT in vivo. Development of an antibody to RemCT will allow tracking of the protein in virus-producing cells. Although there are many other similarities between complex retroviruses like HIV-1 and MMTV, current evidence suggests that Rem lacks an HIV Tat-like transactivator function. / text
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Role of CDP in MMTV transcriptional regulation and tumorigenesisZhu, Quan 14 April 2011 (has links)
Not available / text
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Effect of dietary fatty acids on the expression of the Fgf-3 gene and mouse mammary tumor virus in strain A/St mammary tumorsHalstead, Bartley W. January 1997 (has links)
The specific objective of this study was to determine if Fgf-3 gene expression is mediated by dietary fatty acids and to confirm mouse mammary tumor virus infection. It is well known that dietary linoleic acid enhances growth and dietary stearic acid inhibits growth of mammary tumors. Tumor RNA was extracted from female strain A/St mice fed one of four diets. A radioactively labeled anti-sense RNA probe was generated, invitro, from isolated and purified pFgf-3c (int-2c clone contained in the vector pSP65). The Fgf-3c probe was hybridized to extracted tumor RNA using the ribonuclease protection assay.Electron microscopy confirmed MMTV infection by visualization of type A and B particles in tumor tissue. Expression of Fgf-3c, qualified by RNase protection assay, ranged from 0.02 to 5.89 (relative band density) in all of the diet groups. A positive association between Fgf-3c expression and weight was observed among the tumors of the SA-1 diet (R = 0.947). The SF, SF-1, and PA experimental diets, individually, did not appear to show strong correlation with respect to tumor size. Fgf-3 expression was less in small tumors (<275 mg) and enhanced in large tumors (>275 mg) (p<0.05). / Department of Biology
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The Role of APOBEC3 in Controlling Retroviral Spread and ZoonosesRosales Gerpe, María Carla January 2014 (has links)
APOBEC3 (A3) proteins are a family of host-encoded cytidine deaminases that protect against retroviruses and other viral intruders. Retroviruses, unlike other viruses, are able to integrate their genomic proviral DNA within hours of entering host cells. A3 proteins hinder retroviral infectivity by editing retroviral replication intermediates, as well as by inhibiting retroviral replication and integration through deamination-independent methods. These proteins thus constitute the first line of immune defense against endogenous and exogenous retroviral pathogens. The overall goal of my Master's project was to better understand the critical role A3 proteins play in restricting inter- and intra-host transmission of retroviruses. There are two specific aspects that I focused on: first, investigating the role of mouse APOBEC3 (mA3) in limiting the zoonotic transmission of murine leukemia retroviruses (MLVs) in a rural environment; second, to identify the molecular features in MLVs that confer susceptibility or resistance to deamination by mA3. For the first part of my project, we collected blood samples from dairy and production cattle from four different geographical locations across Canada. We then designed a novel PCR screening strategy targeting conserved genetic regions in MLVs and Mouse Mammary Tumor Virus (MMTV) and MMTV-like betaretroviruses. Our results indicate that 4% of animals were positive for MLV and 2% were positive for MMTV. Despite crossing the species barrier by gaining entry into bovine cells, our study also demonstrates that the bovine A3 protein is able to potently inhibit the spread of these murine retroviruses in vitro. The next question we asked was whether mA3 could also mutate and restrict murine endogenous retroviruses and thereby partake in limiting zoonotic transmission. Moloney MLV and AKV MLV are two highly homologous murine gammaretroviruses with opposite sensitivities to restriction by mA3: MoMLV is resistant to restriction and deamination while AKV is sensitive to both. Design of MoMLV/AKV hybrid viruses enabled us to map the region of mA3 resistance to the region encoding the glyco-Gag accessory protein. Site-directed mutagenesis then allowed us to correlate the number of N-linked glycosylation sites with the level of resistance to deamination by mA3. Our results suggest that Gag glycosylation is a possible viral defence mechanism that arose to counteract the evolutionary pressure imposed by mA3. Overall, my projects show the important role A3 proteins play in intrinsic immunity, whether defending the host from foreign retroviral invaders or endogenous retroviral foes.
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