The function and activity of certain membrane enzymes when localized on – and off – the membrane

Hochstadt, Joy; Quinlan, Dennis C.

doi:10.1002/jcp.1040890452

Cited by 23 publications

(20 citation statements)

References 27 publications

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“…This holds especially for enyzmes. When they are bound to a lipid membrane, many enzymes change their properties and temperature dependencies 2 . In the 1970s, many studies have found deviations from a pure Arrhenius-behavior.…”

Section: Introductionmentioning

confidence: 99%

The activity of the intrinsically water-soluble enzyme ADAMTS13 correlates with the membrane state when bound to a phospholipid bilayer

Kamenac

Obser

Wixforth

et al. 2021

Sci Rep

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Membrane-associated enzymes have been found to behave differently qualitatively and quantitatively in terms of activity. These findings were highly debated in the 1970s and many general correlations and reaction specific models have been proposed, reviewed, and discarded. However, new biological applications brought up the need for clarification and elucidation. To address literature shortcomings, we chose the intrinsically water-soluble enzyme a disintegrin and metalloproteinase with a thrombospondin type 1 motif, member 13 (ADAMTS13) and large unilamellar vesicles with a relative broad phase transition. We here present activity measurements of ADAMTS13 in the freely dissolved state and the membrane associated state for phosphocholine lipids with different acyl-chain lengths (13:0, 14:0 and 15:0) and thus main phase transition temperatures. While the freely dissolved enzyme shows a simple Arrhenius behavior, the activity of membrane associated ADAMTS13 in addition shows a peak. This peak temperature correlates with the main phase transition temperature of the used lipids. These findings support an alternative theory of catalysis. This theory predicts a correlation of the membrane associated activity and the heat capacity, as both are susceptibilities of the same surface Gibb’s free energy, since the enzyme is attached to the membrane.

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Section: Introductionmentioning

confidence: 99%

The activity of the intrinsically water-soluble enzyme ADAMTS13 correlates with the membrane state when bound to a phospholipid bilayer

Kamenac

Obser

Wixforth

et al. 2021

Sci Rep

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“…The phosphoribosylation process, with the high-energy metabolite phosphoribosylpyrophosphate, may simultaneously provide the driving force for the active transport of Hyp and Gua (by group translocation) (13). We have not examined this apparently controversial proposal (15,20), but we have found biphasic Michaelis-Menten plots that suggest the existence of an additional low-affinity transport mechanism for Hyp and Gua (but not for the nucleosides).…”

Section: Discussionmentioning

confidence: 90%

“…The uptake, which was linear for at least 5 min in all cases, is expressed as nanomoles x (OD6oo x minutes)-'; 1 OD6w unit is the amount of cells that gives an OD6w of 1 if the cells are suspended in 1 ml (this corresponds to about 0.5 mg [dry weight] of cells). Except where otherwise stated, the labeled compounds were used at the following concentrations: [2-`4C]Ura, 10 ,uM, 0.1 ,uCi/ml; [8-14CJAde, 10 ,uM, 0.1 ,uCi/ml; [8-14C]Ado, 40 FLM, 0.5 ,Ci/mn; [8-14C]Gua, 20 ,uM, 0.1 ,Ci/ml; [8,5'-3H]Guo, 15 ,uM, 0.5 uCi/ml; [5,6_3H]Uri, 25 ,uM, 0.5 ,Ci/ml; [5-3Hlcytidine, 15 ,uM, 0.5 ,uCi/ml; 1-0-methyl-(a-D-[U-14C]gluco)pyranoside, 50 ,uM, 0.15 ,Ci/ml; or [3-4C]a-aminoisobutyric acid, 100 ,M, 0.1 ,uCi/ml.…”

Section: Methodsmentioning

confidence: 99%

Specificity and control of uptake of purines and other compounds in Bacillus subtilis

Beaman¹,

Hitchins²,

Ochi³

et al. 1983

J Bacteriol

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Certain nucleotides control adaptation to changing nutrition or differentiation (sporulation) resulting from a general nutritional deficiency. To maintain the adaptation or differentiation process, once it has started, it may have been important for cells to evolve several independent and metabolically controllable systems enabling the uptake and metabolism of various nucleic acid bases or nucleosides. We have analyzed the cellular reactions with these compounds by measuring both their effect on growth and their uptake in appropriately chosen auxotrophic and uptake mutants. We have found one uptake system for guanine and hypoxanthine, another one for guanosine and inosine, and three other systems for adenine, adenosine, and uracil. The uptake systems of guaninehypoxanthine and guanosine-inosine are inhibited by the stringent response to amino acid deprivation (increase of guanosine 5'-diphosphate-3'-diphosphate), but they do not depend on the concentration of GTP, which decreases during sporulation. In contrast, the uptake of Ura depends on the presence of GTP, regardless of whether a GTP decrease was produced by the stringent response or otherwise. This was the only uptake system whose decrease was always correlated with the onset of sporulation. The uptake of other compounds, e.g., a

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“…The resultant inosine is metabolized by a purine nucleoside phosphorylase activity, which may or may not be the same as that used in the first mechanism which resulted in extravesicular hypoxanthine, leading to hypoxanthine and additional ribose-l-P. The initial I^evious studies from this laboratory have shown that, when inosine interacts with isolated plasma membrane vesicles from cultured mouse fibroblast cells grown to high cell density, the predominant intravesicular transport product is ribose-l-P1 (Li and Hochstadt, 1976a,b;Hochstadt and Quinlan, 1976). The mechanism involves membrane-localized purine nucleoside phosphorylase acting in a group translocation reaction during which hypoxanthine is released on the exterior membrane surface while the ribose moiety is phosphorylated in the process of being transported across the membrane.In contrast, in polyoma transformed baby hamster kidney (BHK) cells there exist two mechanisms of inosine handling: one, similar to that we have described for the mouse fibroblast cells, in which group translocation occurs and depends on a transmembranal purine nucleoside phosphorylase and for which internal inosine is not a substrate (Hochstadt and Quinlan, 1976;Li and Hochstadt, 1976b) and a second mechanism which involves the uptake of intact inosine.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Mechanism of purine nucleoside handling and transport in isolated membrane vesicles from polyoma transformed BHK/21 cells

Dowd¹,

Quinlan²,

Hochstadt³

1977

Biochemistry

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Inosine uptake into membrane vesicles prepared from baby hamster kidney (BHK) cells appears to proceed by two distinct mechanisms. One mechanism results in the accumulation of ribose 1-phosphate (ribose-l-P) while hypoxanthine is left in the medium. It has a low Km and a high initial rate. Since inosine is cleaved, it is a purine nucleoside phosphorylase dependent step. The second mechanism is purine nucleoside phosphorylase independent and results in intravesicular accumulation of intact inosine. The resultant inosine is metabolized by a purine nucleoside phosphorylase activity, which may or may not be the same as that used in the first mechanism which resulted in extravesicular hypoxanthine, leading to hypoxanthine and additional ribose-l-P. The initial I^evious studies from this laboratory have shown that, when inosine interacts with isolated plasma membrane vesicles from cultured mouse fibroblast cells grown to high cell density, the predominant intravesicular transport product is ribose-l-P1 (Li and Hochstadt, 1976a,b;Hochstadt and Quinlan, 1976). The mechanism involves membrane-localized purine nucleoside phosphorylase acting in a group translocation reaction during which hypoxanthine is released on the exterior membrane surface while the ribose moiety is phosphorylated in the process of being transported across the membrane.In contrast, in polyoma transformed baby hamster kidney (BHK) cells there exist two mechanisms of inosine handling: one, similar to that we have described for the mouse fibroblast cells, in which group translocation occurs and depends on a transmembranal purine nucleoside phosphorylase and for which internal inosine is not a substrate (Hochstadt and Quinlan, 1976;Li and Hochstadt, 1976b) and a second mechanism which involves the uptake of intact inosine. The

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The function and activity of certain membrane enzymes when localized on – and off – the membrane

Cited by 23 publications

References 27 publications

The activity of the intrinsically water-soluble enzyme ADAMTS13 correlates with the membrane state when bound to a phospholipid bilayer

The activity of the intrinsically water-soluble enzyme ADAMTS13 correlates with the membrane state when bound to a phospholipid bilayer

Specificity and control of uptake of purines and other compounds in Bacillus subtilis

Mechanism of purine nucleoside handling and transport in isolated membrane vesicles from polyoma transformed BHK/21 cells

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