-
Something wrong with this record ?
Evaluation of 3-hydroxybutyrate as an enzyme-protective agent against heating and oxidative damage and its potential role in stress response of poly(3-hydroxybutyrate) accumulating cells
S. Obruca, P. Sedlacek, F. Mravec, O. Samek, I. Marova,
Language English Country Germany
Document type Journal Article, Research Support, Non-U.S. Gov't
NLK
ProQuest Central
from 2013-01-01 to 2017-12-31
Medline Complete (EBSCOhost)
from 1999-12-01
Health & Medicine (ProQuest)
from 2013-01-01 to 2017-12-31
- MeSH
- Bacterial Proteins chemistry metabolism MeSH
- Cupriavidus necator chemistry enzymology metabolism MeSH
- Hydroxybutyrates metabolism MeSH
- 3-Hydroxybutyric Acid chemistry metabolism MeSH
- Muramidase chemistry metabolism MeSH
- Protective Agents chemistry metabolism MeSH
- Oxidation-Reduction MeSH
- Oxidative Stress MeSH
- Polyesters metabolism MeSH
- Enzyme Stability MeSH
- Hot Temperature MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
Poly(3-hydroxybutyrate) (PHB) is a common carbon- and energy-storage compound simultaneously produced and degraded into its monomer 3-hydroxybutyrate (3HB) by numerous bacteria and Archae in a metabolic pathway called the PHB cycle. We investigated 3HB as a chemical chaperone capable of protecting model enzymes, namely lipase and lysozyme, from adverse effects of high temperature and oxidation. Heat-mediated denaturation of lipase in the presence or absence of 3HB was monitored by dynamic light scattering (DLS) revealing a significant protective effect of 3HB which increased as its concentration rose. Furthermore, when compared at the same molar concentration, 3HB showed a greater protective effect than the well-known chemical chaperones trehalose and hydroxyectoine. The higher protective effect of 3HB was also confirmed when employing differential scanning calorimetry (DSC) and lysozyme as a model enzyme. Furthermore, 3HB was capable of protecting lipase not only against thermal-mediated denaturation but also against oxidative damage by Cu(2+) and H2O2; its protection was higher than that of trehalose and comparable to that of hydroxyectoine. Taking into account that the PHB-producing strain Cupriavidus necator H16 reveals a 16.5-fold higher intracellular concentration than the PHB non-producing mutant C. necator PHB(-4), it might be expected that the functional PHB cycle might be responsible for maintaining a higher intracellular level of 3HB which, aside from other positive aspects of functional PHB metabolism, enhances stress resistance of bacterial strains capable of simultaneous PHB synthesis and mobilization. In addition, 3HB can be used in various applications and formulations as an efficient enzyme-stabilizing and enzyme-protecting additive.
References provided by Crossref.org
- 000
- 00000naa a2200000 a 4500
- 001
- bmc17000856
- 003
- CZ-PrNML
- 005
- 20170112120927.0
- 007
- ta
- 008
- 170103s2016 gw f 000 0|eng||
- 009
- AR
- 024 7_
- $a 10.1007/s00253-015-7162-4 $2 doi
- 024 7_
- $a 10.1007/s00253-015-7162-4 $2 doi
- 035 __
- $a (PubMed)26590589
- 040 __
- $a ABA008 $b cze $d ABA008 $e AACR2
- 041 0_
- $a eng
- 044 __
- $a gw
- 100 1_
- $a Obruca, Stanislav $u Materials Research Centre, Faculty of Chemistry, Brno University of Technology, Purkynova 118, 612 00, Brno, Czech Republic. Stana.O@seznam.cz.
- 245 10
- $a Evaluation of 3-hydroxybutyrate as an enzyme-protective agent against heating and oxidative damage and its potential role in stress response of poly(3-hydroxybutyrate) accumulating cells / $c S. Obruca, P. Sedlacek, F. Mravec, O. Samek, I. Marova,
- 520 9_
- $a Poly(3-hydroxybutyrate) (PHB) is a common carbon- and energy-storage compound simultaneously produced and degraded into its monomer 3-hydroxybutyrate (3HB) by numerous bacteria and Archae in a metabolic pathway called the PHB cycle. We investigated 3HB as a chemical chaperone capable of protecting model enzymes, namely lipase and lysozyme, from adverse effects of high temperature and oxidation. Heat-mediated denaturation of lipase in the presence or absence of 3HB was monitored by dynamic light scattering (DLS) revealing a significant protective effect of 3HB which increased as its concentration rose. Furthermore, when compared at the same molar concentration, 3HB showed a greater protective effect than the well-known chemical chaperones trehalose and hydroxyectoine. The higher protective effect of 3HB was also confirmed when employing differential scanning calorimetry (DSC) and lysozyme as a model enzyme. Furthermore, 3HB was capable of protecting lipase not only against thermal-mediated denaturation but also against oxidative damage by Cu(2+) and H2O2; its protection was higher than that of trehalose and comparable to that of hydroxyectoine. Taking into account that the PHB-producing strain Cupriavidus necator H16 reveals a 16.5-fold higher intracellular concentration than the PHB non-producing mutant C. necator PHB(-4), it might be expected that the functional PHB cycle might be responsible for maintaining a higher intracellular level of 3HB which, aside from other positive aspects of functional PHB metabolism, enhances stress resistance of bacterial strains capable of simultaneous PHB synthesis and mobilization. In addition, 3HB can be used in various applications and formulations as an efficient enzyme-stabilizing and enzyme-protecting additive.
- 650 _2
- $a kyselina 3-hydroxymáselná $x chemie $x metabolismus $7 D020155
- 650 _2
- $a bakteriální proteiny $x chemie $x metabolismus $7 D001426
- 650 _2
- $a Cupriavidus necator $x chemie $x enzymologie $x metabolismus $7 D020118
- 650 _2
- $a stabilita enzymů $7 D004795
- 650 _2
- $a vysoká teplota $7 D006358
- 650 _2
- $a hydroxybutyráty $x metabolismus $7 D006885
- 650 _2
- $a muramidasa $x chemie $x metabolismus $7 D009113
- 650 _2
- $a oxidace-redukce $7 D010084
- 650 _2
- $a oxidační stres $7 D018384
- 650 _2
- $a polyestery $x metabolismus $7 D011091
- 650 _2
- $a ochranné látky $x chemie $x metabolismus $7 D020011
- 655 _2
- $a časopisecké články $7 D016428
- 655 _2
- $a práce podpořená grantem $7 D013485
- 700 1_
- $a Sedlacek, Petr $u Materials Research Centre, Faculty of Chemistry, Brno University of Technology, Purkynova 118, 612 00, Brno, Czech Republic.
- 700 1_
- $a Mravec, Filip $u Materials Research Centre, Faculty of Chemistry, Brno University of Technology, Purkynova 118, 612 00, Brno, Czech Republic.
- 700 1_
- $a Samek, Ota $u Institute of Scientific Instruments, v.v.i., Czech Academy of Sciences, Kralovopolska 147, 612 64, Brno, Czech Republic.
- 700 1_
- $a Marova, Ivana $u Materials Research Centre, Faculty of Chemistry, Brno University of Technology, Purkynova 118, 612 00, Brno, Czech Republic.
- 773 0_
- $w MED00000493 $t Applied microbiology and biotechnology $x 1432-0614 $g Roč. 100, č. 3 (2016), s. 1365-76
- 856 41
- $u https://pubmed.ncbi.nlm.nih.gov/26590589 $y Pubmed
- 910 __
- $a ABA008 $b sig $c sign $y a $z 0
- 990 __
- $a 20170103 $b ABA008
- 991 __
- $a 20170112121026 $b ABA008
- 999 __
- $a ok $b bmc $g 1179996 $s 961423
- BAS __
- $a 3
- BAS __
- $a PreBMC
- BMC __
- $a 2016 $b 100 $c 3 $d 1365-76 $e 20151121 $i 1432-0614 $m Applied microbiology and biotechnology $n Appl Microbiol Biotechnol $x MED00000493
- LZP __
- $a Pubmed-20170103
