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Adenovirus Regulation of Host Cell Cycle and DNA ReplicationKafle, Chandra Mani 28 June 2022 (has links)
No description available.
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Regulation of productivity in Trichoplusia ni and Spodoptera frugiperda Sf9 serum-free culturesCalles, Karin January 2005 (has links)
<p>The aim of this work has been to characterize the effects of conditioned medium (CM) on insect cell productivity and physiology in order to get a better understanding about the mechanisms that regulate productivity in serum-free media. Two cell lines have been investigated, Spodoptera frugiperda (Sf9) and Trichoplusia ni (T. ni, BTI-Tn-5B1-4). The baculovirus expression vector system (BEVS) was used for protein expression, using the ligand-binding domain of the human glucocorticoid receptor as a model protein. Addition of CM at inoculation led to a shorter lag phase and that the cells reached the maximum cell density faster than cells in fresh medium for both Sf9 and T. ni cells. Sf9 cells passed a switch in growth kinetics after 30-40 passages. At this point, CM lost its stimulating effect on proliferation. CM also affected the cell size and cell cycle progression. Sf9 and T. ni cells became smaller when CM was added at inoculation because they had a minor arrest in the cell cycle after inoculation and therefore started to divide earlier than cells in fresh medium. For Sf9 cells, this was illustrated by a smaller arrest in G2/M in the beginning of culture and the cells were consequently less synchronized. For T. ni cells, the initial decrease in the S phase population was followed by an earlier increase of the S phase population for the cells with CM than for the cells in fresh medium.</p><p>Addition of 20 % CM or CM filtrated with a 10 kDa cut-off filter to Sf9 cultures had a negative effect on the specific productivity. However, addition of CM to Sf9 cells that had passed the switch in growth kinetics had no negative effect on productivity. This indicates that CM not affects the protein production per se, but rather through its effects on cell physiology. Instead, the degree of cells synchronized in G2/M is important for high productivity and the gradually decreasing degree of synchronization during the course of a culture might be the explanation behind the cell density dependent decrease in productivity for Sf9 cells. This was further supported by the positive effects on productivity achieved by synchronizing Sf9 cells in G2/M by yeastolate limitation, which counteracted the cell density-dependent drop in productivity and hence a higher volumetric yield was achieved. Addition of 20 % CM to T. ni cultures had a positive effect on productivity. The specific productivity was maintained at a high level longer than for cells in 100 % fresh medium. The product concentration was 34 % higher and the maximum product concentration was obtained 24 hours earlier for the cells with the addition of CM. These results show that the effects of CM on productivity are not the same for the two cell lines and that the mechanism regulating productivity are quite complex.</p>
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Mutated in colorectal cancer (MCC): a putative tumour suppressor gene in colorectal cancerSigglekow, Nicholas David, Garvan Institute of Medical Research, Faculty of Medicine, UNSW January 2009 (has links)
Colorectal cancer (CRC) remains a significant burden in contemporary society due to an aging population, unhealthy dietary choices and an increasingly sedentary lifestyle. While the underlying defects for many hereditary forms of CRC have been determined, many genetic and epigenetic changes promoting common sporadic CRCs have yet to be identified. The Mutated in Colorectal Cancer (MCC) gene, identified in 1991, was initially thought to be responsible for the hereditary form of CRC, familial adenomatous polyposis, before the discovery of the susceptibility gene Adenomatous Polyposis Coli (APC), which then became the focus of intense research. Recent data, however, suggests that MCC may also be important in the development of CRC. I have investigated the mechanism of MCC gene silencing, the putative structure, and multiple functions of MCC. MCC was frequently silenced by promoter hypermethylation in CRC cell lines and primary tumours. MCC methylation showed strong molecular and clinicopathological associations with hallmarks of the serrated neoplasia pathway. Furthermore, MCC methylation was more frequent in serrated precursor lesions compared with adenomas, thus occurring early during carcinogenesis. MCC is highly conserved in complex multicellular organisms. Re-introduction of MCC in CRC cell lines resulted in partial G1 to S phase, and G2/M phase cell cycle blocks, potentially by upregulating cell cycle inhibitor gene transcription and interfering with the process of mitotic checkpoints and division, respectively. Changes in MCC levels also modulated NF?B pathway signalling, the pathway required for maintaining cell viability and proliferation in colonic epithelial cells. In particular, MCC overexpression suppressed both TNF? and LPS-induced NF?B activation, decreasing both the magnitude and rate of cellular responses. Overexpression also resulted in downregulation of proteins involved in canonical NF?B pathway signalling, while increasing the transcription of non-canonical NF?B genes. Therefore, MCC may direct activation of this pathway to a specific subset of NF?B-regulated genes. These data provide a molecular basis for the role of MCC as a tumour suppressor gene in CRC. MCC may have multiple functions, regulating cell cycle progression and modulating NF?B pathway signalling, either through direct involvement in pathway signalling cascades, or by providing a scaffold on which signalling events can occur.
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Mutated in colorectal cancer (MCC): a putative tumour suppressor gene in colorectal cancerSigglekow, Nicholas David, Garvan Institute of Medical Research, Faculty of Medicine, UNSW January 2009 (has links)
Colorectal cancer (CRC) remains a significant burden in contemporary society due to an aging population, unhealthy dietary choices and an increasingly sedentary lifestyle. While the underlying defects for many hereditary forms of CRC have been determined, many genetic and epigenetic changes promoting common sporadic CRCs have yet to be identified. The Mutated in Colorectal Cancer (MCC) gene, identified in 1991, was initially thought to be responsible for the hereditary form of CRC, familial adenomatous polyposis, before the discovery of the susceptibility gene Adenomatous Polyposis Coli (APC), which then became the focus of intense research. Recent data, however, suggests that MCC may also be important in the development of CRC. I have investigated the mechanism of MCC gene silencing, the putative structure, and multiple functions of MCC. MCC was frequently silenced by promoter hypermethylation in CRC cell lines and primary tumours. MCC methylation showed strong molecular and clinicopathological associations with hallmarks of the serrated neoplasia pathway. Furthermore, MCC methylation was more frequent in serrated precursor lesions compared with adenomas, thus occurring early during carcinogenesis. MCC is highly conserved in complex multicellular organisms. Re-introduction of MCC in CRC cell lines resulted in partial G1 to S phase, and G2/M phase cell cycle blocks, potentially by upregulating cell cycle inhibitor gene transcription and interfering with the process of mitotic checkpoints and division, respectively. Changes in MCC levels also modulated NF?B pathway signalling, the pathway required for maintaining cell viability and proliferation in colonic epithelial cells. In particular, MCC overexpression suppressed both TNF? and LPS-induced NF?B activation, decreasing both the magnitude and rate of cellular responses. Overexpression also resulted in downregulation of proteins involved in canonical NF?B pathway signalling, while increasing the transcription of non-canonical NF?B genes. Therefore, MCC may direct activation of this pathway to a specific subset of NF?B-regulated genes. These data provide a molecular basis for the role of MCC as a tumour suppressor gene in CRC. MCC may have multiple functions, regulating cell cycle progression and modulating NF?B pathway signalling, either through direct involvement in pathway signalling cascades, or by providing a scaffold on which signalling events can occur.
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Molecular and functional characterization of ABRAXAS and PALB2 genes in hereditary breast cancer predispositionBose, M. (Muthiah) 29 October 2019 (has links)
Abstract
Hereditary mutations in DNA damage response (DDR) genes often lead to genomic instability and ultimately tumor development. However, the molecular mechanism of how these DDR deficiencies promote genomic instability and malignancy is not well understood. Thus, the specific aim of this thesis is to identify the functional and molecular framework behind the elevated breast cancer risk observed in heterozygous PALB2 and ABRAXAS mutation carriers.
The heterozygous germline alteration in PALB2 (c.1592delT) causes a haploinsufficiency phenotype in the mutation carrier cells. Due to PALB2 haploinsufficiency, elevated Cdk activity and consequently aberrant DNA replication/damage response was observed in the PALB2 mutation carrier cells. Excessive origin firing that is indicative of replication stress was also seen in the PALB2 mutation carrier cells. In addition to replication stress, PALB2 mutation carrier cells also experience G2/M checkpoint maintenance defects. The increased malignancy risk in females associated with heterozygosity for the Finnish PALB2 founder mutation is likely to be due to aberrant DNA replication, elevated genomic instability and multiple different cell cycle checkpoint defects.
The heterozygous germline alteration in ABRAXAS (c.1082G>A) causes a dominant-negative phenotype in the mutation carrier cells. Decreased BRCA1 protein levels as well as reduced nuclear localization and foci formation of BRCA1 and CtIP was observed in the ABRAXAS mutation carrier cells. This causes disturbances in basal BRCA1-A complex localization, which is reflected by a restraint in error-prone DNA double-strand break (DSB) repair pathway usage, attenuated DNA damage response, deregulated G2/M checkpoint control and apoptosis. Most importantly, mutation carrier cells display a change in their transcriptional profile, which we attribute to the reduced nuclear levels of BRCA1. Thus, the Finnish ABRAXAS founder mutation acts in a dominant-negative manner on BRCA1 to promote genome destabilization in the heterozygous carrier cells. / Tiivistelmä
Perinnölliset muutokset DNA-vauriovasteen geeneissä johtavat usein genomin epävakauteen ja lopulta syövän kehittymiseen. Molekyylitason mekanismeja, joilla vauriovasteen vajaatoiminta ajaa genomin epävakautta ja syöpää, ei kuitenkaan ymmärretä kunnolla. Tämän väitöskirjan tavoitteena on tunnistaa solutoiminnan ja molekyylitason vaikuttajat heterotsygoottisten PALB2- ja ABRAXAS-geenimuutosten kantajien kohonneen rintasyöpäriskin taustalla.
Heterotsygoottinen ituradan suomalainen perustajamuutos PALB2-geenissä (c.1592delT) aiheuttaa haploinsuffisienssin kantajahenkilöiden soluissa. PALB2:n haploinsuffisienssin seurauksena kantajasoluissa havaittiin kohonnutta Cdk-proteiinin aktiivisuutta ja siitä johtuvaa kiihtynyttä DNA:n kahdentumista. PALB2-mutaatiota kantavissa soluissa nähtiin myös liiallista replikaation aloituskohtien käyttöä, mikä viittaa replikaatiostressiin. Replikaatiostressin lisäksi PALB2-mutaation kantajasoluilla havaittiin vaikeuksia ylläpitää solusyklin G2/M-tarkastuspisteen toimintaa. Näiden solutoiminnan poikkeavuuksien takia heterotsygoottisen PALB2 c.1592delT -mutaation kantajilla todettiin genomin epävakautta ja kohonnut syöpäriski.
Heterotsygoottinen ituradan mutaatio ABRAXAS-geenissä (c.1082G>A) aiheuttaa dominantti-negatiivisen fenotyypin mutaation kantajasoluissa. ABRAXAS-mutaatiota kantavissa soluissa havaittiin BRCA1-proteiinitasojen laskua sekä BRCA1- ja CtIP-proteiinien vähentynyttä lokalisaatiota tumaan ja DNA-vauriopaikoille. Tämä aiheuttaa häiriöitä BRCA1-A-kompleksin paikallistumisessa, mikä johtaa häiriöihin virhealttiiden DNA-kaksoisjuoste¬katkoksien korjausmekanismien käytössä, DNA-vauriovasteessa, G2/M-tarkastus-pisteen säätelyssä ja ohjelmoidussa solukuolemassa. Tärkeimpänä löydöksenä havaittiin mutaation kantajasoluissa muuttunut transkriptioprofiili, joka johtunee BRCA1-proteiinitasojen laskusta tumassa. Näin ollen suomalainen ABRAXAS-perustajamutaatio toimii dominantti-negatiivisena BRCA1:n suhteen, aiheuttaen genomin epävakautta heterotsygoottisissa kantajasoluissa.
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Regulation of productivity in Trichoplusia ni and Spodoptera frugiperda Sf9 serum-free culturesCalles, Karin January 2005 (has links)
The aim of this work has been to characterize the effects of conditioned medium (CM) on insect cell productivity and physiology in order to get a better understanding about the mechanisms that regulate productivity in serum-free media. Two cell lines have been investigated, Spodoptera frugiperda (Sf9) and Trichoplusia ni (T. ni, BTI-Tn-5B1-4). The baculovirus expression vector system (BEVS) was used for protein expression, using the ligand-binding domain of the human glucocorticoid receptor as a model protein. Addition of CM at inoculation led to a shorter lag phase and that the cells reached the maximum cell density faster than cells in fresh medium for both Sf9 and T. ni cells. Sf9 cells passed a switch in growth kinetics after 30-40 passages. At this point, CM lost its stimulating effect on proliferation. CM also affected the cell size and cell cycle progression. Sf9 and T. ni cells became smaller when CM was added at inoculation because they had a minor arrest in the cell cycle after inoculation and therefore started to divide earlier than cells in fresh medium. For Sf9 cells, this was illustrated by a smaller arrest in G2/M in the beginning of culture and the cells were consequently less synchronized. For T. ni cells, the initial decrease in the S phase population was followed by an earlier increase of the S phase population for the cells with CM than for the cells in fresh medium. Addition of 20 % CM or CM filtrated with a 10 kDa cut-off filter to Sf9 cultures had a negative effect on the specific productivity. However, addition of CM to Sf9 cells that had passed the switch in growth kinetics had no negative effect on productivity. This indicates that CM not affects the protein production per se, but rather through its effects on cell physiology. Instead, the degree of cells synchronized in G2/M is important for high productivity and the gradually decreasing degree of synchronization during the course of a culture might be the explanation behind the cell density dependent decrease in productivity for Sf9 cells. This was further supported by the positive effects on productivity achieved by synchronizing Sf9 cells in G2/M by yeastolate limitation, which counteracted the cell density-dependent drop in productivity and hence a higher volumetric yield was achieved. Addition of 20 % CM to T. ni cultures had a positive effect on productivity. The specific productivity was maintained at a high level longer than for cells in 100 % fresh medium. The product concentration was 34 % higher and the maximum product concentration was obtained 24 hours earlier for the cells with the addition of CM. These results show that the effects of CM on productivity are not the same for the two cell lines and that the mechanism regulating productivity are quite complex. / QC 20101125
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