Rowland J. Burgess scite author profile

Analysis of the reversible unfolding of yeast phosphoglycerate kinase leads to the conclusion that the two lobes are capable of folding independently, consistent with the presence of intermediates on the folding pathway with a single domain folded. The domains have different free energies of stabilisation. Immunological crossreactivity, circular dichroism and thiol reactivity provide evidence for cyanogen bromide peptide 1 -173, which comprises five-sixths of the N-terminal domain, containing sufficient information to refold into a native-like structure which dimerises. Domains were first defined by examination of X-ray crystallographic structures of proteins [I]. There [7] studied the unfolding of a human kappa light chain and interpreted their results in terms of intermediates on the folding pathway, having one domain folded and the other unfolded. They showcd that there is little, if any, interaction between the two domains.

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Protein degradation in rat liver during post-natal development

Russell¹,

Burgess²,

Mayer³

1980

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Protein degradation rates for liver subcellular and submitochondrial fractions from neonatal (8-day), weanling (25-day) and adult rats were estimated by the double-isotope method with NaH14CO3 and [3H] arginine as the radiolabelled precursors [Dice, Walker, Byrne & Cardiel (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 2093-2097]. Decreased protein degradation rates were found during post-natal development for homogenate, nuclear, mitochondrial, lysosomal and microsomal proteins. A decrease in degradation rates for the immunoisolated subunits of monoamine oxidase and pyruvate dehydrogenase was also observed in neonatal and weanling rats respectively. The results suggest coordinate degradation of the subunits of the multi-subunit enzyme pyruvate dehydrogenase. Pyruvate dehydrogenase has a faster rate of degradation in adult rat liver than does cytochrome oxidase. Data analysis suggests heterogeneity of protein degradation rates in the mitochondrial outer membrane and intermembrane space fractions at each developmental stage but not in the mitochondrial inner membrane or matrix fractions. Results obtained for protein degradation rates in adult rat liver by the method of Burgess, Walker & Mayer [(1978) Biochem. J. 176, 919-926] in general confirmed the results obtained for the adult rat liver by the above method. No evidence of a subunit-size relationship for protein degradation was found for proteins in any subcellular or submitochondrial fraction.

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Choice of precursors for the measurement of protein turnover by the double-isotope method. Application to the study of mitochondrial proteins

Burgess¹,

Walker²,

Mayer³

1978

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1. The double-isotope concept [Arias, Doyle & Schimke (1969) J. Biol. Chem. 224, 3303--3315] for the measurement of protein turnover was used to estimate the turnover of proteins in subcellular and submitochondrial fractions prepared from rat liver. 2. Double-isotope experiments with [3H]leucine as first precursor and [14C]leucine as second precursor were used to measure the turnover rates of proteins in subcellular and submitochondrial fractions. Solvent extraction procedures designed to remove lipids and nucleic acids from trichloroacetic acid precipitates only changed the isotope ratio of the microsomal fraction. It was not possible to measure turnover of proteins in mitochondrial and submitochondrial fractions with these precursors. 3. Double-isotope experiments were designed to minimize first-precursor reutilization by employing NaH14CO3. [3H]Arginine was used as second precursor. The turnover rates of protein in subcellular and submitochondrial fractions was measured. Solvent extraction procedures designed to remove lipids and nucleic acids showed changes in the isotope ratio for all subcellular fractions, especially in microsomal and detergent-soluble mitochondrial fractions. Isotope ratios of precipitates after solvent extraction indicate that, whereas considerable heterogeneity exists for the average rates of protein turnover in subcellular fractions, little heterogeneity is observed in the average rates of protein turnover in submitochondrial fractions.

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Relative rates of turnover of subunits of mitochondrial proteins

Walker¹,

Burgess²,

Mayer³

1978

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1. The double-isotope concept [Arias, Doyle & Schimke (1969) J. Biol. Chem. 244, 3303--3315] for the measurement of protein turnover was used to estimate the turnover rates of protein subunits from rat liver submitochondrial fractions resolved by means of polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate. NaH14CO3 and [5-3H]arginine were used as first and second precursors respectively. 2. Marked heterogeneity of protein subunit turnover rates is seen for protein subunits from water-soluble, salt-soluble and Tween 20-soluble mitochondrial proteins. 3. Much lower heterogeneity is seen in the turnover of protein subunits in Triton X-100-soluble material not binding to DEAE-cellulose at low ionic strength. The relative rates of turnover of proteins in this fraction are lower than for proteins in any other submitochondrial fraction. This fraction contains the integral membrane proteins. 4. Incorporation of [3H]arginine into subunits of the cytochrome oxidase complex is greatest for subunits with molecular weights in excess of 20000. 5. No correlation is seen between protein subunit size and the rate of turnover of the protein subunits in any of the submitochondrial fractions.

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Factors Controlling Intracellular Breakdown of Proteins

Mayer

Burgess

Russell

1980

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