The surface of oxygen-plasma-treated polystyrene (PSox) was investigated using X-ray photoelectron
spectroscopy (XPS), streaming potential measurements and a dynamic study of the wetting properties at
different pH (Wilhelmy plate method). The PSox surface is functionalized with various oxygen-containing
groups, including carboxyl functions, and must be viewed as covered by a polyelectrolyte which swells
depending on pH. The wetting hysteresis, its evolution upon repeated cycles and the influence of pH are
controlled by the dissolution of functionalized fragments and the retention of water upon emersion; the
retained water may evaporate progressively and allow macromolecule compaction and/or reorientation.
Modification of the PSox surface upon aging in dry atmosphere, humid atmosphere, and water was studied
using XPS and dynamic wetting measurements. Aging in water provoked the dissolution of PSox
macromolecular chains, as indicated by adsorption of released fragments on a check PS sample placed
nearby. However, the concentration of functionalized molecules at the surface of water-aged PSox was still
sufficient to allow swelling at pH 5.6 and 11.0. Hydrophobicity recovery was faster in humid air (R. H.
95%) compared to dry air (R. H. 5%), due to the plasticizing effect of water. Hydrophobicity recovery upon
aging in air was reversed quickly by immersion at pH 5.6 or 11.0, due to deprotonation and swelling.
Effects of salt stress on polyamine metabolism and ethylene production were examined in two rice (Oryza sativa L.) cultivars [I Kong Pao (IKP), salt sensitive; and Pokkali, salt resistant] grown for 5 d and 12 d in nutrient solution in the presence or absence of putrescine (1 mM) and 0, 50, and 100 mM NaCl. The salt-sensitive (IKP) and salt-resistant (Pokkali) cultivars differ not only in their mean levels of putrescine, but also in the physiological functions assumed by this molecule in stressed tissues. Salt stress increased the proportion of conjugated putrescine in salt-resistant Pokkali and decreased it in the salt-sensitive IKP, suggesting a possible protective function in response to NaCl. Activities of the enzymes ornithine decarboxylase (ODC; EC 4.1.1.17) and arginine decarboxylase (ADC; EC 4.1.1.19) involved in putrescine synthesis were higher in salt-resistant Pokkali than in salt-sensitive IKP. Both enzymes were involved in the response to salt stress. Salt stress also increased diamine oxidase (DAO; 1.4.3.6) and polyamine oxidase (PAO EC 1.5.3.11) activities in the roots of salt-resistant Pokkali and in the shoots of salt-sensitive IKP. Gene expression followed by reverse transcription-PCR suggested that putrescine could have a post-translational impact on genes coding for ADC (ADCa) and ODC (ODCa and ODCb) but could induce a transcriptional activation of genes coding for PAO (PAOb) mainly in the shoot of salt-stressed plants. The salt-resistant cultivar Pokkali produced higher amounts of ethylene than the salt-sensitive cultivar IKP, and exogenous putrescine increased ethylene synthesis in both cultivars, suggesting no direct antagonism between polyamine and ethylene pathways in rice.
The adsorption of proteins at biomaterial surfaces depends on the properties of the substrate and can
cause changes in protein conformation. Time-of-flight secondary ion mass spectroscopy (ToF-SIMS) was
used in this study to characterize human serum albumin (HSA) adsorption on two different polycarbonate
surfaces: a native membrane and a hydrophilic treated one. The amount adsorbed as a function of HSA
concentration in solution was compared for the two substrates. The treated membrane was found to have
a lower affinity for albumin than the native one. Principal component analysis was used to reveal changes
in albumin conformation as a function of albumin concentration in solution and to compare the conformations
adopted on the two substrates. The albumin conformation was different on the two substrates, and in every
case, the protein lost its native structure. A correlation was found between the amount adsorbed on the
hydrophilic surface and the albumin conformation on this surface.
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