Identification of Crocin as a New hIAPP Amyloid Inhibitor via a Simple Yet Highly Biospecific Screening System.

Amylin (hIAPP) amyloid formation plays an important role in the pathogenesis of type 2 diabetes (T2D), which makes it a promising therapeutic target for T2D. In this study, we established a screening tool for identifying chemicals affecting hIAPP amyloid formation based on a reported genetic tool, which constantly tracks protein aggregates in Saccharomyces cerevisiae. In order to obtain the hIAPP with better aggregation ability, the gene of hIAPP was tandemly ligated to create 1×, 2×, 4× or 6×-hIAPP expressing strains. By measuring the cell density and fluorescence intensity of green fluorescent protein (GFP) regulated by the aggregation status of hIAPP, it was found that four intramolecular ligated hIAPP (4×hIAPP) could form obvious amyloids with mild toxicity. The validity and reliability of the screening tool were verified by testing six reported hIAPP inhibitors, including curcumin, epigallocatechin gallate and so on. Combined with surface plasmon resonance (SPR) and the screening tool, which could be a screening system for hIAPP inhibitors, we found that crocin specifically binds to hIAPP and acts inhibit amyloid formation of hIAPP. The effect of crocin was further confirmed by Thioflavin T (ThT) fluorescence and transmission electron microscopy (TEM) analysis. Thus, a screening system for hIAPP amyloid inhibitors and a new mechanism of crocin on anti-T2D were obtained as a result of this study.

Characterization of the hydrolysate and catalytic cavity of α-agarase AgaD.

OBJECTIVE: To characterize the hydrolysis product and the substrate binding in the catalytic cavity of α-agarase AgaD. RESULTS: The time course curve showed that AgaD degraded agarose by the endo-type cleavage. AgaD did not degrade agarobiose (A2) and agarotetraose (A4). The minimum-length substrate was agarohexaose (A6), which was cleaved into A2 and A4. Agarooctaose (A8) was cleaved into two molecules of A4. Consistently, TLC and NMR data identified agarotetraose (A4) as the main hydrolysate when agarose was degraded by AgaD. CONCLUSION: This study confirms AgaD is an endo-type α-agarase and A4 as the main hydrolysis product of AgaD, which suggests the catalytic cavity of AgaD accommodates eight sugar units spanning from - 4 to + 4.

Chitosan Oligosaccharides Attenuate Amyloid Formation of hIAPP and Protect Pancreatic ß-Cells from Cytotoxicity.

The deposition of aggregated human islet amyloid polypeptide (hIAPP) in the pancreas, that has been associated with ß-cell dysfunction, is one of the common pathological features of patients with type 2 diabetes (T2D). Therefore, hIAPP aggregation inhibitors hold a promising therapeutic schedule for T2D. Chitosan oligosaccharides (COS) have been reported to exhibit a potential antidiabetic effect, but the function of COS on hIAPP amyloid formation remains elusive. Here, we show that COS inhibited the aggregation of hIAPP and disassembled preformed hIAPP fibrils in a dose-dependent manner by thioflavin T fluorescence assay, circular dichroism spectroscopy, and transmission electron microscope. Furthermore, COS protected mouse ß-cells from cytotoxicity of amyloidogenic hIAPP, as well as apoptosis and cycle arrest. There was no direct binding of COS and hIAPP, as revealed by surface plasmon resonance analysis. In addition, both chitin-oligosaccharide and the acetylated monosaccharide of COS and glucosamine had no inhibition effect on hIAPP amyloid formation. It is presumed that, mechanistically, COS regulate hIAPP amyloid formation relating to the positive charge and degree of polymerization. These findings highlight the potential role of COS as inhibitors of hIAPP amyloid formation and provide a new insight into the mechanism of COS against diabetes.

Characterization of an α-agarase from Thalassomonas sp. LD5 and its hydrolysate.

It has been a long time since the first α-agarase was discovered. However, only two α-agarases have been cloned and partially characterized so far and the study of α-agarases has lagged far behind that of ß-agarases. Here, we report an α-agarase, AgaD, cloned from marine bacterium Thalassomonas sp. LD5. Its cDNA consists of 4401 bp, encoding a protein of 1466 amino acids. Based on amino acid similarity, AgaD is classified into glycoside hydrolase (GH) family GH96. The recombinant enzyme gave a molecular weight of about 180 kDa on SDS-PAGE and 360 kDa on Native-PAGE indicating it acted as a dimer. However, the recombinant enzyme is labile and easy to be fractured into series of small active fragments, of which the smallest one is about 70 kDa, matching the size of catalytic module. The enzyme has maximal activity at 35 °C and pH 7.4, and shows a strong dependence on the presence of calcium ions. AgaD degrades agarose to yield agarotetraose as the predominate end product. However, the hydrolysates are rapidly degraded to odd-numbered oligosaccharides under strong alkaline condition. The spectra of ESI-MS and 1H-NMR proved that the main hydrolysate agarotetraose is degraded into neoagarotriose, bearing the sequence of G-A-G (G, D-galactose; A, 3,6-anhydro-α-L-galactose). Unlike the alkaline condition, the hydrolysates are further hydrolyzed into smaller degree polymerization (DP) of agaro-oligosaccharides (AOS) in dilute strong acid. Therefore, this study provides more insights into the properties for both the α-agarases and the AOS.

N-Terminal seven-amino-acid extension simultaneously improves the pH stability, optimal temperature, thermostability and catalytic efficiency of chitosanase CsnA.

OBJECTIVE: To determine the effects of the extra N-terminal seven-amino-acid sequence on the function of chitosanase CsnA. RESULTS: Sequence and structure analysis indicated that the mature CsnA contains a seven-amino-acid extension in a disordered form at the N-terminus. To determine the function of this sequence, both mature CsnA and its N-terminus-truncated mutant, CsnAΔN, were expressed in Escherichia coli and characterized. Compared with CsnAΔN, CsnA exhibited a 15 °C higher temperature optimum, enhanced pH stability, thermostability and catalytic efficiency. The underlying mechanisms responsible for these changes were analyzed by circular dichroism (CD) spectroscopy. CD analysis revealed that the deletion of the N-terminal sequence resulted in a decrease in the Tm of 4.3 °C and this sequence altered the secondary structure of the enzyme. CONCLUSIONS: The N-terminal sequence is essential for the stability and activity of chitosanase CsnA.

Erratum to: N-Terminal seven-amino-acid extension simultaneously improves the pH stability, optimal temperature, thermostability and catalytic efficiency of chitosanase CsnA.

In Table 1 as published, some of the data were wrong. The corrected Table 1 is shown below.

Erratum to: Thermostability enhancement of chitosanase CsnA by fusion a family 5 carbohydrate-binding module.

In Table 1 as published, some of the data were wrong. The corrected Table 1 is shown here. In addition, according to the corrected Table 1, the sentence "the k cat /K m of CsnA-CBM5 was higher than that of WT by 143%" in the part of "The kinetic parameters and specific activity" in the Results part should be changed to "the k cat /K m of CsnA-CBM5 was higher than that of WT by 110%".

Thermostability enhancement of chitosanase CsnA by fusion a family 5 carbohydrate-binding module.

OBJECTIVE: To determine the effects of carbohydrate-binding modules (CBMs) on the thermostability and catalytic efficiency of chitosanase CsnA. RESULTS: Three CBMs (BgCBM5, PfCBM32-2 and AoCBM35) were engineered at the C-terminus of chitosanase CsnA to create hybrid enzymes CsnA-CBM5, CsnA-CBM32 and CsnA-CBM35. K m values of all the hybrid enzymes were lower than that of the wild type (WT) enzyme; however, only CsnA-CBM5 had an elevated specific activity and catalytic efficiency. The fusion of BgCBM5 enhanced the thermostability of the enzyme, which exhibited a 8.9 °C higher T50 and a 2.9 °C higher Tm than the WT. Secondary structural analysis indicated that appending BgCBM5 at the C-terminus considerably changed the secondary structure content. CONCLUSIONS: The fusion of BgCBM5 improved the thermal stability of CsnA, and the obtained hybrid enzyme (CsnA-CBM5) is a useful candidate for industrial application.

[High expression of agarase AgaD in Escherichia coli].

OBJECTIVE: We constructed highly efficient expression systems for agarase AgaD and optimized its culture conditions. METHODS: First, the codon usage of AgaD was optimized to make it suitable for expression in E. coli. Then, the gene expression vector was transformed into different E. coli hosts. According to the "N-end rule" that is related to the in vivo half-life of a protein, a mutant was constructed. Finally, the effects of CaCl2 and glycine on enzyme production were evaluated. RESULTS: A highly efficient expression system of agarase AgaD was constructed, named pET-22b (+)-optagaDx-AD494 ( E3). Replacing N-terminal second amino acid phenylalanine with alanine significantly improved agarase production and shortened the fermentation period. The extracellular enzyme activity was further up-regulated by CaCll and glycine. After optimization, the extracellular enzyme production raised from 20 U/L to 11300 U/L, more than 500 folds. CONCLUSION: The high expression system of AgaD provides good basis for further studying agarases.

Chitosan oligosaccharides alleviate macrophage pyroptosis and protect sepsis mice via activating the Nrf2/GPX4 pathway.

In the process of sepsis, excessive occurrence of pyroptosis, a form of programmed cell death acting as a defense mechanism against pathogens, can disrupt immune responses, thus leading to tissue damage and organ dysfunction. Chitosan oligosaccharide (COS), derived from chitosan degradation, has demonstrated diverse beneficial effects. However, its impact on sepsis-induced pyroptosis remains unexplored. In the present study, ATP/LPS was utilized to induce canonical-pyroptosis in THP-1 cells, while bacterial outer membrane vesicles (OMV) were employed to trigger non-canonical pyroptosis in RAW264.7 cells. Our results revealed a dose-dependent effect of COS on both types of pyroptosis. This was evidenced by a reduction in the expression of pro-inflammatory cytokines, as well as crucial regulatory proteins involved in pyroptosis. In addition, COS inhibited the cleavage of caspase-1 and GSDMD, and reduced ASC oligomerization. The underlying mechanism revealed that COS acts an antioxidant, reducing the release of pyroptosis-induced ROS and malondialdehyde (MDA) by upregulation the expression and promoting the nuclear translocation of nuclear factor erythroid-2-related factor 2 (Nrf2), which led to an elevation of glutathione peroxidase 4 (GPX4) and superoxide dismutase (SOD). Notably, the actions of COS were completely reversed by the Nrf2 inhibitor. Consequently, COS intervention increased the survival rate of sepsis.

Artificial trans-encoded small non-coding RNAs specifically silence the selected gene expression in bacteria.

Recently, many small non-coding RNAs (sRNAs) with important regulatory roles have been identified in bacteria. As their eukaryotic counterparts, a major class of bacterial trans-encoded sRNAs acts by basepairing with target mRNAs, resulting in changes in translation and stability of the mRNA. RNA interference (RNAi) has become a powerful gene silencing tool in eukaryotes. However, such an effective RNA silencing tool remains to be developed for prokaryotes. In this study, we described first the use of artificial trans-encoded sRNAs (atsRNAs) for specific gene silencing in bacteria. Based on the common structural characteristics of natural sRNAs in Gram-negative bacteria, we developed the designing principle of atsRNA. Most of the atsRNAs effectively suppressed the expression of exogenous EGFP gene and endogenous uidA gene in Escherichia coli. Further studies demonstrated that the mRNA base pairing region and AU rich Hfq binding site were crucial for the activity of atsRNA. The atsRNA-mediated gene silencing was Hfq dependent. The atsRNAs led to gene silencing and RNase E dependent degradation of target mRNA. We also designed a series of atsRNAs which targeted the toxic genes in Staphyloccocus aureus, but found no significant interfering effect. We established an effective method for specific gene silencing in Gram-negative bacteria.

Endotoxin accelerates insulin amyloid formation and inactivates insulin signal transduction.

AIMS AND OBJECTIVES: The aim of this study is to discuss the influence of endotoxin on insulin amyloid formation, to provide guidance for therapeutic insulin preparation and storage. MATERIALS AND METHODS: The ThT and ANS binding assays were applied to characterize the dynamics curve of insulin amyloid formation with the presence or absence of endotoxin. The morphological structures of intermediate and mature insulin fibrils were observed with SEM and TEM. Secondary structural changes of insulin during fibriliation were examined with CD, FTIR and Raman spectral analysis. The cytotoxic effects of oligomeric and amyloidogenic insulin aggregates were detected using a cck-8 cell viability assay kit. The influence of endotoxin on insulin efficacy was analyzed by monitoring the activation of insulin signal transduction. KEY FINDINGS: ThT analysis showed that endotoxin, regardless of species, accelerated insulin fibrils formation in a dose-dependent manner, as observed with a shorter lag phase. ANS binding assay demonstrated endotoxin provoked the exposure of insulin hydrophobic patches. The results of SEM and TEM data displayed that endotoxin drove insulin to cluster into dense and viscous form, with thicker and stronger filaments. Based on CD, FTIR and Raman spectra, endotoxin promoted the transition of α-helix to random coil and ß-strand secondary structures during insulin aggregation. Insulins in both oligomeric and amyloidogenic forms were cytotoxic to HepG2 cells, with the former being more severe. Finally, the efficacy of endotoxin treated insulin obviously decreased. SIGNIFICANCE: Our studies revealed that endotoxin disrupts the structural integrity of insulin and promotes its amyloidosis. These findings offered theoretical guidance for insulin storage and safe utilization, as well as pointing up a new direction for insulin resistance research.

Characterizing of a new α-agarase AgaE from Thalassomonas sp. LD5 and probing its catalytically essential residues.

A new α-agarase AgaE belonging to glycoside hydrolase (GH) family 96 was identified and cloned from marine bacterium Thalassomonas sp. LD5. AgaE consists of 926 amino acids with a theoretical molecular mass of 97 kDa. The optimum temperature and pH for recombinant AgaE were 35 °C and 7.0, respectively. In contrast to known α-agarases, the activity of AgaE does not depend on Ca2+, but on Na+. Thin-layer chromatography and 13C NMR analysis revealed that AgaE endohydrolytic of agarose to produce agarotetraose and agarohexaose as the final main products. Extensive site-directed mutagenesis studies on the conserved carboxylic amino acids of GH96 revealed two essential amino acids for AgaE, D779 and D781. Replacing D779 with G779 leads to complete inactivation of the enzyme, while D781G results in 70% loss of activity. Later studies showed that site D781 involved in the binding of Na+, and its mutation raised the optimal concentration of Na+ 4 times higher than that of the wild type. However, attempts to rescue the mutant's activities with sodium azide were failed. Kinetic parameters comparison of AgaE, AgaD, another α-agarase from LD5, and their mutants revealed that the former aspartic acid plays critical role in the catalysis.

[Construction of Staphylococcus aureus RN6390 hmp gene mutant and analysis of NO sensitivity].

OBJECT: To investigate the function of flavohaemoglobin (HMP) in Staphylococcus aureus RN6390 under the nitrification pressure, we constructed the hmp gene deletion mutant of RN6390 strain. METHODS: According to principle of homologous recombination, we obtained the up stream and down stream sequences of hmp gene by PCR using chromosomal DNA of S. aureus RN6390 as template. Antibiotics pressure and alternating temperature culture were applied for mutant strain selection. We verified the clones screened out by genome PCR and real-time PCR quantification. Sodium nitroprusside (SNP), as nitric oxide (NO) donor, was used for NO resistance evaluation. In addition, we compared the bacteria biofilm formation ability of hmp gene mutant strain with wild type. RESULTS: We successfully constructed hmp gene mutant strain of S. aureus RN6390. The expression of hmp gene was direct correlate with the concentration of exogenous NO. We found that compared to wild type, the mutant strain was more sensitive to NO and it is prone to form bacteria biofilm. CONCLUSIONS: The successfully constructed hmp gene deletion mutant of S. aureus provided the possibilities to further investigate the biological function of hmp gene in the resistance of S. aureus to NO from host immune system.

Cloning, expression and characterization of a new agarase-encoding gene from marine Pseudoalteromonas sp.

The beta-agarase gene agaA, cloned from a marine bacterium, Pseudoalteromonas sp. CY24, consists of 1,359 nucleotides encoding 453 amino acids in a sequence corresponding to a catalytic domain of glycosyl hydrolase family 16 (GH16) and a carbohydrate-binding module type 13 (CBM13). The recombinant enzyme is an endo-type agarase that hydrolyzes beta-1,4-linkages of agarose, yielding neoagarotetraose and neoagarohexaose as the predominant products. In two cleavage patterns, AgaA digested the smallest substrate, neoagarooctaose, into neoagarobiose, neoagarotetraose and neoagarohexaose. Site directed mutation was performed to investigate the differences between AgaA and AgaD of Vibrio sp. PO-303, identifying residues V(109)VTS(112) as playing a key role in the enzyme reaction.

Silencing of GM3 synthase suppresses lung metastasis of murine breast cancer cells.

BACKGROUND: Gangliosides are sialic acid containing glycosphingolipids that are ubiquitously distributed on vertebrate plasma membranes. GM3, a precursor for most of the more complex ganglioside species, is synthesized by GM3 synthase. Although total ganglioside levels are significantly higher in breast tumor tissue than in normal mammary tissue, the roles played by gangliosides in breast cancer formation and metastasis are not clear. METHODS: To investigate the roles of gangliosides in breast tumor development, GM3 synthase was silenced in the highly metastatic 4T1 cells and over-expressed in the non-metastatic 67NR cells. The behavior of breast cancer cells was examined in vitro using migration assay, invasion assay, and soft agar assay. Tumor formation and metastasis in vivo were examined using a well established mouse mammary tumor model. RESULTS: GM3 synthase silencing in 4T1 cells significantly inhibited cell migration, invasion and anchorage-independent growth in vitro, and lung metastasis in vivo. In addition, over-expression of GM3 synthase in nonmetastatic 67NR cells significantly induced cell migration and anchorage-independent growth. Further studies indicated that activation of the phosphoinositide-3 kinase/Akt pathway, and consequently inhibition of nuclear factor of activated T cell (NFAT)1 expression, could be the mechanism underlying the suppression of breast cancer migration/invasion induced by GM3 synthase silencing. CONCLUSION: Our findings indicate that GM3 synthase silencing suppressed lung metastasis in murine breast cancer cells. The molecular mechanism that underlies GM3 synthase mediated migration and invasion was inhibition of the phosphoinositide-3 kinase/Akt pathway. The findings suggest that GM3 synthase may be of value as a therapeutic target in breast cancer.

The hydrogen-bond network around Glu160 contributes to the structural stability of chitosanase CsnA from Renibacterium sp. QD1.

CsnA, a chitosanase from Renibacterium sp. QD1, has great potential for industrial applications due to its high yield and broad pH stability. In this study, a specific Glu160 in CsnA was identified by sequence alignment, and structural analysis and MD simulation predicted that Glu160 formed a hydrogen-bond network with Lys163 and Thr114. To evaluate the effect of the network, we constructed four mutants, including E160A, E160Q, K163A, and T114A, which partially or completely destroy this network. Characterization of these mutants demonstrated that the disruption of the network significantly decreased the enzyme thermostability. The underlying mechanisms responsible for the change of thermostability analyzed by circular dichroism spectroscopy revealed that the hydrogen-bond network conferred the structural stability of CsnA. Moreover, the length of the side chain of residue at 160 impacted conformational stability of the enzyme. Taken together, the hydrogen-bond network around Glu160 plays important roles in stabilization of CsnA.

A simple method of preparing diverse neoagaro-oligosaccharides with beta-agarase.

In order to prepare pure and well-defined oligosaccharides from agarose in a rapid and simple manner, an enzymatic degradation method was developed, which includes degradation with either recombinant beta-agarase (EC 3.2.1.81) AgaA or AgaB and gel permeation chromatography. Agarose was degraded with AgaA at the optimized conditions, yielding 47% and 45% of neoagarotetraose and neoagarohexaose, respectively. These neoagaro-oligosaccharides were conveniently separated by consecutive column chromatography on Bio-Gel P2 or P6 and were identified by FACE. The structure of these neoagaro-oligosaccharides was confirmed by MALDI-TOF MS and (13)C NMR spectroscopy.

O-GlcNAcylation of SIRT1 enhances its deacetylase activity and promotes cytoprotection under stress.

SIRT1 is the most evolutionarily conserved mammalian sirtuin, and it plays a vital role in the regulation of metabolism, stress responses, genome stability, and ageing. As a stress sensor, SIRT1 deacetylase activity is significantly increased during stresses, but the molecular mechanisms are not yet fully clear. Here, we show that SIRT1 is dynamically modified with O-GlcNAc at Ser 549 in its carboxy-terminal region, which directly increases its deacetylase activity both in vitro and in vivo. The O-GlcNAcylation of SIRT1 is elevated during genotoxic, oxidative, and metabolic stress stimuli in cellular and mouse models, thereby increasing SIRT1 deacetylase activity and protecting cells from stress-induced apoptosis. Our findings demonstrate a new mechanism for the activation of SIRT1 under stress conditions and suggest a novel potential therapeutic target for preventing age-related diseases and extending healthspan.