Your search keyword '"Roobol, Anne"' showing total 5 results

1. Engineered transient and stable overexpression of translation factors eIF3i and eIF3c in CHOK1 and HEK293 cells gives enhanced cell growth associated with increased c-Myc expression and increased recombinant protein synthesis.

Author

Roobol, Anne, Roobol, Joanne, Smith, Matthew E., Carden, Martin J., Hershey, John W.B., Willis, Anne E., and Smales, C. Mark

Subjects

*RECOMBINANT proteins, *PROTEIN synthesis, *CHO cell, *CELL growth, *CELLS, *CELL proliferation

Abstract

There is a desire to engineer mammalian host cell lines to improve cell growth/biomass accumulation and recombinant biopharmaceutical protein production in industrially relevant cell lines such as the CHOK1 and HEK293 cell lines. The over-expression of individual subunits of the eukaryotic translation factor eIF3 in mammalian cells has previously been shown to result in oncogenic properties being imparted on cells, including increased cell proliferation and growth and enhanced global protein synthesis rates. Here we report on the engineering of CHOK1 and HEK cells to over-express the eIF3i and eIF3c subunits of the eIF3 complex and the resultant impact on cell growth and a reporter of exogenous recombinant protein production. Transient over-expression of eIF3i in HEK293 and CHOK1 cells resulted in a modest increase in total eIF3i amounts (maximum 40% increase above control) and an approximate 10% increase in global protein synthesis rates in CHOK1 cells. Stable over-expression of eIF3i in CHOK1 cells was not achievable, most likely due to the already high levels of eIF3i in CHO cells compared to HEK293 cells, but was achieved in HEK293 cells. HEK293 cells engineered to over-express eIF3i had faster growth that was associated with increased c-Myc expression, achieved higher cell biomass and gave enhanced yields of a reporter of recombinant protein production. Whilst CHOK1 cells could not be engineered to over-express eIF3i directly, they could be engineered to over-express eIF3c, which resulted in a subsequent increase in eIF3i amounts and c-Myc expression. The CHOK1 eIF3c engineered cells grew to higher cell numbers and had enhanced cap- and IRES-dependent recombinant protein synthesis. Collectively these data show that engineering of subunits of the eIF3 complex can enhance cell growth and recombinant protein synthesis in mammalian cells in a cell specific manner that has implications for the engineering or selection of fast growing or high producing cells for production of recombinant proteins. • We have engineered the overexpression of eIF3i and eIF3c in CHOK1 and HEK293 cells. • HEK293 cells overexpressing eIF3i had faster growth and increased c-Myc expression. • Direct stable overexpression of eIF3i in CHOK1 cells was not achievable. • Overexpression of eIF3c in CHOK1 cells resulted in an increase in eIF3i. • eIF3c overexpressing CHOK1 cells had enhanced recombinant protein synthesis. [ABSTRACT FROM AUTHOR]

Published

2020

2. p58IPK is an inhibitor of the eIF2ɑ kinase GCN2 and its localization and expression underpin protein synthesis and ER processing capacity.

Author

Roobol, Anne, Roobol, Jo, Bastide, Amandine, Knight, John R. P., Willis, Anne E., and Smales, C. Mark

Subjects

*GENE expression, *INITIATION factors (Biochemistry), *PROTEIN synthesis, *PROTEIN kinases, *ENDOPLASMIC reticulum, *MESSENGER RNA

Abstract

One of the key cellular responses to stress is the attenuation of mRNA translation and protein synthesis via the phosphorylation of eIF2ɑ (eukaryotic translation initiation factor 2ɑ). This is mediated by four eIF2ɑ kinases and it has been suggested that each kinase is specific to the cellular stress imposed. In the present study, we show that both PERK (PKR-like endoplasmic reticulum kinase/eIF2ɑ kinase 3) and GCN2 (general control non-derepressible 2/eIF2ɑ kinase 4) are required for the stress responses associated with conditions encountered by cells overexpressing secreted recombinant protein. Importantly, whereas GCN2 is the kinase that is activated following cold-shock/hypothermic culturing of mammalian cells, PERK and GCN2 have overlapping functions since knockdown of one of these at the mRNA level is compensated for by the cell by up-regulating levels of the other. The protein p58IPK {also known as DnaJ3C [DnaJ heat-shock protein (hsp) 40 homologue, subfamily C, member 3]} is known to inhibit the eIF2ɑ kinases PKR (dsRNA-dependent protein kinase/eIF2ɑ kinase 2) and PERK and hence prevent or delay eIF2ɑ phosphorylation and consequent inhibition of translation. However, we show that p58IPK is a general inhibitor of the eIF2ɑ kinases in that it also interacts with GCN2. Thus forced overexpression of cytoplasmic p58 delays eIF2ɑ phosphorylation, suppresses GCN2 phosphorylation and prolongs protein synthesis under endoplasmic reticulum (ER), hypothermic and prolonged culture stress conditions. Taken together, our data suggest that there is considerable cross talk between the eIF2ɑ kinases to ensure that protein synthesis is tightly regulated. Their activation is controlled by p58 and the expression levels and localization of this protein are crucial in the capacity the cells to respond to cellular stress via control of protein synthesis rates and subsequent folding in the ER. [ABSTRACT FROM AUTHOR]

Published

2015

3. Eukaryotic elongation factor 2 kinase regulates the cold stress response by slowing translation elongation.

Author

Knight, John R. P., Bastide, Amandine, Roobol, Anne, Roobol, Jo, Jackson, Thomas J., Utami, Wahyu, Barrett, David A., Smales, C. Mark, and Willis, Anne E.

Subjects

ELONGATION factors (Biochemistry), PHYSIOLOGICAL effects of cold temperatures, GENETIC translation, GENE expression, PROTEIN synthesis, APOPTOSIS

Abstract

Cells respond to external stress conditions by controlling gene expression, a process which occurs rapidly via post-transcriptional regulation at the level of protein synthesis. Global control of translation is mediated by modification of translation factors to allow reprogramming of the translatome and synthesis of specific proteins that are required for stress protection or initiation of apoptosis. In the present study, we have investigated how global protein synthesis rates are regulated upon mild cooling. We demonstrate that although there are changes to the factors that control initiation, including phosphorylation of eukaryotic translation initiation factor 2 (eIF2) on the a-subunit, the reduction in the global translation rate is mediated by regulation of elongation via phosphorylation of eukaryotic elongation factor 2 (eEF2) by its specific kinase, eEF2K (eukaryotic elongation factor 2 kinase). The AMP/ATP ratio increases following cooling, consistent with a reduction in metabolic rates, giving rise to activation of AMPK (5'-AMP-activated protein kinase), which is upstream of eEF2K. However, our data show that the major trigger for activation of eEF2K upon mild cooling is the release of Ca2+ ions from the endoplasmic reticulum (ER) and, importantly, that it is possible to restore protein synthesis rates in cooled cells by inhibition of this pathway at multiple points. As cooling has both therapeutic and industrial applications, our data provide important new insights into how the cellular responses to this stress are regulated, opening up new possibilities to modulate these responses for medical or industrial use at physiological or cooler temperatures. [ABSTRACT FROM AUTHOR]

Published

2015

4. RTN3 Is a Novel Cold-Induced Protein and Mediates Neuroprotective Effects of RBM3

Author

Bastide, Amandine, Peretti, Diego, Knight, John RP, Grosso, Stefano, Spriggs, Ruth V, Pichon, Xavier, Sbarrato, Thomas, Roobol, Anne, Roobol, Jo, Vito, Davide, Bushell, Martin, Von Der Haar, Tobias, Smales, C Mark, Mallucci, Giovanna R, and Willis, Anne E

Subjects

mRNA translation, protein synthesis, Cold-Shock Response, RBM3, RTN3, RNA-Binding Proteins, Nerve Tissue Proteins, 3. Good health, Cold Temperature, Mice, cold shock, HEK293 Cells, Neuroprotective Agents, Cold Shock Proteins and Peptides, Animals, Humans, neuroprotection

Abstract

Cooling and hypothermia are profoundly neuroprotective, mediated, at least in part, by the cold shock protein, RBM3. However, the neuroprotective effector proteins induced by RBM3 and the mechanisms by which mRNAs encoding cold shock proteins escape cooling-induced translational repression are unknown. Here, we show that cooling induces reprogramming of the translatome, including the upregulation of a new cold shock protein, RTN3, a reticulon protein implicated in synapse formation. We report that this has two mechanistic components. Thus, RTN3 both evades cooling-induced translational elongation repression and is also bound by RBM3, which drives the increased expression of RTN3. In mice, knockdown of RTN3 expression eliminated cooling-induced neuroprotection. However, lentivirally mediated RTN3 overexpression prevented synaptic loss and cognitive deficits in a mouse model of neurodegeneration, downstream and independently of RBM3. We conclude that RTN3 expression is a mediator of RBM3-induced neuroprotection, controlled by novel mechanisms of escape from translational inhibition on cooling.

5. RTN3 Is a Novel Cold-Induced Protein and Mediates Neuroprotective Effects of RBM3.

Author

Bastide, Amandine, Peretti, Diego, Knight, John R.P., Grosso, Stefano, Spriggs, Ruth V., Pichon, Xavier, Sbarrato, Thomas, Roobol, Anne, Roobol, Jo, Vito, Davide, Bushell, Martin, von der Haar, Tobias, Smales, C. Mark, Mallucci, Giovanna R., and Willis, Anne E.

Subjects

*NEUROPROTECTIVE agents, *HYPOTHERMIA, *COLD shock proteins, *MESSENGER RNA, *GENETIC code

Abstract

Summary Cooling and hypothermia are profoundly neuroprotective, mediated, at least in part, by the cold shock protein, RBM3. However, the neuroprotective effector proteins induced by RBM3 and the mechanisms by which mRNAs encoding cold shock proteins escape cooling-induced translational repression are unknown. Here, we show that cooling induces reprogramming of the translatome, including the upregulation of a new cold shock protein, RTN3, a reticulon protein implicated in synapse formation. We report that this has two mechanistic components. Thus, RTN3 both evades cooling-induced translational elongation repression and is also bound by RBM3, which drives the increased expression of RTN3. In mice, knockdown of RTN3 expression eliminated cooling-induced neuroprotection. However, lentivirally mediated RTN3 overexpression prevented synaptic loss and cognitive deficits in a mouse model of neurodegeneration, downstream and independently of RBM3. We conclude that RTN3 expression is a mediator of RBM3-induced neuroprotection, controlled by novel mechanisms of escape from translational inhibition on cooling. [ABSTRACT FROM AUTHOR]

Published

2017