An unknown protein reacted with anti-human IgA, namely, IgA-like protein, has been reported in shrimp, but information regarding its identification is not available. In the present study, an affinity proteomic strategy was applied to identify the IgA-like protein of shrimp Litopenaeus vannamei. The protein of 75 kDa was isolated and confirmed by affinity chromatography and Western blotting with goat anti-human IgA, respectively, and then identified as hemocyanin, a member of IgSF, by mass spectrometry. Moreover, our results showed that human IgA and L. vannamei hemocyanin could separately react with goat anti-human IgA or rabbit anti-shrimp affinity hemocyanin (a-hemocyanin). Further evidences indicated that the recombinant protein of the Ig-like conserved domain could react with anti-human IgA. Interestingly, our results indicated that L. vannamei hemocyanin could aggregate with eight species of shrimp pathogenic bacteria and four types of animal erythrocytes directly. These results indicate that L. vannamei hemocyanin, an IgA-like protein, has dual function of reaction with anti-human IgA as an antigen and of activity binding to bacteria and animal erythrocytes as an agglutinin, suggesting its characteristic role as an IgSF molecule. In addition, our approach suggests that affinity proteomics based on heterogeneous antibody can speed up the identification of Fossman antigens.
Polydicyclopentadiene (PDCPD) is
a tough, heavily crosslinked thermoset
polymer that has high heat, chemical, and impact resistance coupled
with a low density. Current limitations to the broader industrial
application of PDCPD include its low surface energy and lack of chemical
tunability. Here, we report the first example of a polymer derived
from a carboxyl-functionalized dicyclopentadiene monomer and its subsequent
thermal crosslinking. The resulting material has the highest glass-transition
temperature reported for a polydicyclopentadiene and allows for the
facile manipulation of the surface chemistry through alteration of
the embedded functional group. We also report the first observation
by differential scanning calorimetry of the crosslinking step as a
discreet thermal event.
The physicochemical properties of chitosan obtained from the shells of swimming crab (Portunus trituberculatus) and prepared via subcritical water pretreatment were examined. At the deacetylation temperature of 90 °C, the yield, ash content, and molecular weight of chitosan in the shells prepared via subcritical water pretreatment were 12.2%, 0.6%, and 1187.2 kDa, respectively. These values were lower than those of shells prepared via sodium hydroxide pretreatment. At the deacetylation temperature of 120 °C, a similar trend was observed in chitosan molecular weight, but differences in chitosan yield and ash content were not remarkable. At the same deacetylation temperature, the structures of chitosan prepared via sodium hydroxide and subcritical water pretreatments were not substantially different. However, the compactness and thermal stability of chitosan prepared via sodium hydroxide pretreatment was lower than those of chitosan prepared via subcritical water pretreatment. Compared with the chitosan prepared by sodium hydroxide pretreatment, the chitosan prepared by subcritical water pretreatment was easier to use in preparing oligosaccharides, including (GlcN)2, via enzymatic hydrolysis with chitosanase. Results suggested that subcritical water pretreatment can be potentially used for the pretreatment of crustacean shells. The residues obtained via this method can be utilized to prepare chitosan.
The
simple structural modification of replacing a terminal carboxylic
acid with a primary amide group was found to lower the minimum gelation
concentration (MGC), by at least an order of magnitude, for a series
of
N
-lauroyl-
l
-amino acid phase-selective
organogelators in decane. The amide-functionalized analogue
N
-lauroyl-
l
-alanine-CONH
2
was demonstrated
to gel a broad range of solvents from diesel to THF at MGCs of 2.5%
w/v or less, as well as to produce gels with a higher thermal stability
(
ca.
30 °C) and enhanced mechanical properties
(5 times increase in complex modulus), compared to the carboxylic
acid analogue,
N
-lauroyl-
l
-alanine-COOH.
These improved properties may be due to the additional hydrogen bonding
in the primary amide analogue as revealed by SCXRD. Most significantly
for this study, the introduction of the primary amide functionality
enabled
N
-lauroyl-
l
-alanine-CONH
2
to form a self-assembled fibrillar network in water. The aqueous
network could then actively uptake and rapidly gel decane, diesel,
and diluted bitumen (“dilbit”) with MGCs of 2.5% w/v
or less. This aqueous delivery method is advantageous for oil-remediation
applications as no harmful carrier solvents are required and the gel
can be easily separated from the water, allowing the oil to be recovered
and the gelator recycled.
Using panel data from China, we find a positive relationship between philanthropic engagement and investment efficiency. In addition, we find that the positive association between philanthropy and investment efficiency is stronger when the company is located in a region with better institutional environments. Our results suggest that companies engaging in philanthropic donations have incentives to enhance their reputation and/or promote their relationships with stakeholders, leading to lower agency problems and higher investment efficiency.
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