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1. Post-translational events of a model reporter protein proceed with higher fidelity and accuracy upon mild hypothermic culturing of Chinese hamster ovary cells

Author

Masterton, Rosalyn J., Roobol, Anne, Al-Fageeh, Mohamed B., Carden, Martin J., Smales, Christopher Mark, Masterton, Rosalyn J., Roobol, Anne, Al-Fageeh, Mohamed B., Carden, Martin J., and Smales, Christopher Mark

Abstract

Chinese hamster ovary cells (CHO) are routinely used in industry to produce recombinant therapeutic proteins and a number of studies have reported increased recombinant mRNA levels at temperatures <37°C. Surprisingly, the effect of reduced temperature on mRNA translation in CHO cells has not been investigated despite this process being highly responsive to environmental stresses. The relationship between low temperature culturing of CHO cells and mRNA translation was therefore investigated using labeling studies and dual luciferase reporter gene technology. Global protein synthetic capacity was not greatly affected at 32°C but was diminished at lower temperatures. The expression of both cap-dependent and cap-independent (IRES driven) mRNA translated luciferase reporter gene activity was highest at 32°C on a per cell basis and this was partially accounted for by increased mRNA levels. Importantly, post-translational events appear to proceed with higher fidelity and accuracy at 32°C than 37oC resulting in increased yield of active protein as opposed to an increase in total polypeptide synthesis. Therefore at 32°C recombinant cap-dependent mRNA translation appears sufficient to maintain recombinant protein yields on a per cell basis and this is associated with improved post-translational processing.

Published
2010

2. Slow axonal transport of the cytosolic chaperonin CCT with Hsc73 and actin in motor neurons

Author

Carden, Martin J., Roobol, Anne, El Alami, Wathik, Wilson, Suzanne J., Bourke, Gregory J., Carden, Martin J., Roobol, Anne, El Alami, Wathik, Wilson, Suzanne J., and Bourke, Gregory J.

Abstract

Molecular chaperones are well known for their role in facilitating the folding of nascent and newly synthesized proteins, but have other roles, including the assembly, translocation and renaturation of intracellular proteins. Axons are convenient tissues for the study of some of these other roles because they lack the capacity for significant protein synthesis. We examine the axonal transport of the cytosolic chaperonin containing T- complex polypeptide 1 (CCT) by labeling lumbar motor neurons with [35S]methionine and examining sciatic nerve proteins by 2-D gel electrophoresis and immunoblotting. All CCT subunits identifiable with specific antibodies, namely CCT?, CCT?, CCT? and CCT?/CCT? (the latter two subunits colocalized in analyses of rat nerve samples), appeared to be labeled in “slow component b” of axonal transport along with the molecular chaperone Hsc73 and actin, a major folding substrate for CCT. Our results are consistent with molecular chaperones having a post-translational role in maintaining the native form of actin during its slow transport to the axon terminal and ensuring its correct assembly into microfilaments. © 2002 Wiley-Liss, Inc.

Published
2002

3. Disassembly of the cytosolic chaperonin in mammalian cell extracts at intracellular levels of K+ and ATP

Author

Roobol, Anne, Grantham, J., Whitaker, H.C., Carden, Martin J., Roobol, Anne, Grantham, J., Whitaker, H.C., and Carden, Martin J.

Abstract

The eukaryotic, cytoplasmic chaperonin, CCT, is essential for the biogenesis of actin- and tubulin-based cytoskeletal structures. CCT purifies as a doubly toroidal particle containing two eight-membered rings of similar to 60-kDa ATPase subunits, each encoded by an essential and highly conserved gene. However, immunofluorescence detection with subunit-specific antibodies has indicated that in cells CCT subunits do not always colocalize. We report here that CCT ATPase activity is highly dependent on K+ ion concentration and that in cell extracts, at physiological levels of K+ and ATP, there is considerable dissociation of CCT to a smaller oligomeric structure and free subunits. This dissociation is consequent to ATP hydrolysis and is readily reversed on removal of ATP. The ranking order for ease with which subunits can exit the chaperonin particle correlates well with the length of a loop structure, identified by homology modeling, in the intermediate domain of CCT subunits. K+-ATP-induced disassembly is not an intrinsic property of purified CCT over a 80-fold concentration range and requires the presence of additional factor(s) present in cell extracts.

Published
1999

4. Selected subunits of the cytosolic chaperonin associate with microtubules assembled in vitro

Author

Roobol, Anne, Sahyoun, Z.P., Carden, Martin J., Roobol, Anne, Sahyoun, Z.P., and Carden, Martin J.

Abstract

The molecular chaperone activities of the only known chaperonin in the eukaryotic cytosol (cytosolic chaperonin containing T-complex polypeptide 1 (CCT)) appear to be relatively specialized; the main folding substrates in vivo and in vitro are identified as tubulins and actins. CCT is unique among chaperonins in the complexity of its hetero-oligomeric structure, containing eight different, although related, gene products. In addition to their known ability to bind to and promote correct folding of newly synthesized and denatured tubulins, we show here that CCT subunits alpha, gamma, zeta, and theta also associated with in vitro assembled microtubules, i.e. behaved as microtubule-associated proteins. This nucleotide-dependent association between microtubules and CCT polypeptides (K-d similar to 0.1 mu M CCT subunit) did not appear to involve whole oligomeric chaperonin particles, but rather free CCT subunits. Removal of the tubulin COOH termini by subtilisin digestion caused all eight CCT subunits to associate with the microtubule polymer, thus highlighting the non-chaperonin nature of the selective CCT subunit association with normal microtubules.

Published
1999

5. Subunits of the eukaryotic cytosolic chaperonin CCT do not always behave as components of a uniform hetero-oligomeric particle

Author

Roobol, Anne, Carden, Martin J., Roobol, Anne, and Carden, Martin J.

Abstract

The chaperonin CCT is an hetero-oligomeric molecular chaperone complex. Studies in yeast suggest each of its eight gene products are required for its major identified functions in producing native tubulins and actins, However, it is unclear whether these eight components always form a single particle, covering all functions, or else can also exist as heterogeneous mixtures and/or free subunits in cells. Using mouse P19 embryonal carcinoma cells, which divide rapidly, yet in retinoic acid adopt a neuronal phenotype, admired with occasional (similar to 10 %) fibroblast-like cells, together with a panel of peptide-specific antibodies raised to 7 of the 8 CCT subunits we show that; (1) adoption of a post mitotic phenotype is accompanied by reduced CCT protein expression, significantly more so for CCT beta, CCT delta, CCT epsilon, and CCT theta than for CCT alpha (TCP-1), CCT gamma and CCT zeta; (2) CCT alpha is detected preferentially over other subunits in neurites of P19 neurons; (3) small amounts of CCT alpha and gamma are localised in nuclei (i.e. are not exclusively cytoplasmic), selectively so compared with other subunits; (4) numerous cytosolic foci exist in the cytoplasm which, when detected by double immunofluorescence can contain only one of the subunits probed for; (5) while a "core" chaperonin particle can be immunoprecipitated under native conditions, epitope access is modified both by nucleotides and by non-CCT co-precipitating proteins. Collectively, these findings indicate that CCT subunits are not only components of the hetero-oligomeric chaperonin particle but exist as significant populations of free subunits or smaller oligomers in cells.

Published
1999

6. Disassembly of the cytosolic chaperonin in mammalian cell extracts at intracellular levels of K+ and ATP

Author

Roobol, Anne, Grantham, J., Whitaker, H.C., Carden, Martin J., Roobol, Anne, Grantham, J., Whitaker, H.C., and Carden, Martin J.

Abstract

The eukaryotic, cytoplasmic chaperonin, CCT, is essential for the biogenesis of actin- and tubulin-based cytoskeletal structures. CCT purifies as a doubly toroidal particle containing two eight-membered rings of similar to 60-kDa ATPase subunits, each encoded by an essential and highly conserved gene. However, immunofluorescence detection with subunit-specific antibodies has indicated that in cells CCT subunits do not always colocalize. We report here that CCT ATPase activity is highly dependent on K+ ion concentration and that in cell extracts, at physiological levels of K+ and ATP, there is considerable dissociation of CCT to a smaller oligomeric structure and free subunits. This dissociation is consequent to ATP hydrolysis and is readily reversed on removal of ATP. The ranking order for ease with which subunits can exit the chaperonin particle correlates well with the length of a loop structure, identified by homology modeling, in the intermediate domain of CCT subunits. K+-ATP-induced disassembly is not an intrinsic property of purified CCT over a 80-fold concentration range and requires the presence of additional factor(s) present in cell extracts.

Published
1999

17. Identification of chaperonin particles in mammalian brain cytosol and of T-complex polypeptide 1 as one of their components.

Author

Roobol, Anne, Carden, Martin J., Roobol, Anne, and Carden, Martin J.

Abstract

An approximately 950-kDa heteromeric particle was purified from guinea-pig and rat brain by sucrose gradient fractionation of post-mitochondrial supernatants. Further purification, by affinity chromatography on ATP-Sepharose and anion exchange FPLC on MonoQ, yielded a particle with typical chaperonin ultrastructure. One of the component polypeptides was recognized by a monoclonal antibody to murine T-complex polypeptide 1. Brain cytosolic chaperonin particles formed a binary complex with unfolded tubulin subunits. The polypeptide compositions of the cytosolic chaperonin particles appeared very similar between brain and testicular tissues of the same animal, but differed subtly between the guinea-pig and rat.

Published
1993

18. Identification of chaperonin particles in mammalian brain cytosol and of T-complex polypeptide 1 as one of their components.

Author

Roobol, Anne, Carden, Martin J., Roobol, Anne, and Carden, Martin J.

Abstract

An approximately 950-kDa heteromeric particle was purified from guinea-pig and rat brain by sucrose gradient fractionation of post-mitochondrial supernatants. Further purification, by affinity chromatography on ATP-Sepharose and anion exchange FPLC on MonoQ, yielded a particle with typical chaperonin ultrastructure. One of the component polypeptides was recognized by a monoclonal antibody to murine T-complex polypeptide 1. Brain cytosolic chaperonin particles formed a binary complex with unfolded tubulin subunits. The polypeptide compositions of the cytosolic chaperonin particles appeared very similar between brain and testicular tissues of the same animal, but differed subtly between the guinea-pig and rat.

Published
1993

19. Identification of chaperonin particles in mammalian brain cytosol and of T-complex polypeptide 1 as one of their components.

Author

Roobol, Anne, Carden, Martin J., Roobol, Anne, and Carden, Martin J.

Abstract

An approximately 950-kDa heteromeric particle was purified from guinea-pig and rat brain by sucrose gradient fractionation of post-mitochondrial supernatants. Further purification, by affinity chromatography on ATP-Sepharose and anion exchange FPLC on MonoQ, yielded a particle with typical chaperonin ultrastructure. One of the component polypeptides was recognized by a monoclonal antibody to murine T-complex polypeptide 1. Brain cytosolic chaperonin particles formed a binary complex with unfolded tubulin subunits. The polypeptide compositions of the cytosolic chaperonin particles appeared very similar between brain and testicular tissues of the same animal, but differed subtly between the guinea-pig and rat.

Published
1993

20. Identification of chaperonin particles in mammalian brain cytosol and of T-complex polypeptide 1 as one of their components.

Author

Roobol, Anne, Carden, Martin J., Roobol, Anne, and Carden, Martin J.

Abstract

An approximately 950-kDa heteromeric particle was purified from guinea-pig and rat brain by sucrose gradient fractionation of post-mitochondrial supernatants. Further purification, by affinity chromatography on ATP-Sepharose and anion exchange FPLC on MonoQ, yielded a particle with typical chaperonin ultrastructure. One of the component polypeptides was recognized by a monoclonal antibody to murine T-complex polypeptide 1. Brain cytosolic chaperonin particles formed a binary complex with unfolded tubulin subunits. The polypeptide compositions of the cytosolic chaperonin particles appeared very similar between brain and testicular tissues of the same animal, but differed subtly between the guinea-pig and rat.

Published
1993

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