Hyperosmotic stress induces phosphorylation of cytosolic phospholipase A(2) in HaCaT cells by an epidermal growth factor receptor-mediated process

Cytosolic phospholipase A(2) (cPLA(2)) is an enzyme involved in the formation of proinflammatory mediators by catalyzing the release of arachidonic acid, thereby mediating eicosanoid biosynthesis. Using HaCaT keratinocytes as a model system, we present experimental evidence that in these cells, cPLA(2) is constitutively phosphorylated and that the degree of phosphorylation dramatically increases in cells under hyperosmotic stress induced by sorbitol. In parallel, a rapid release of arachidonic acid followed by prostaglandin E(2) formation was detected. Elucidating the mechanism of cPLA(2) upregulation, we observed that it is mediated via epidermal growth factor receptor (EGFR) activation, since tyrphostin AG1478, a selective inhibitor of EGFR tyrosine kinase, completely inhibited cPLA(2) phosphorylation. Furthermore, addition of PD98059, which is an inhibitor of MEK1 activation, but not of SB203580, which is an inhibitor of p38 stress kinase, inhibited cPLA(2) phosphorylation, indicating that the ras-raf-MEK cascade is the major signalling pathway involved in cPLA(2) phosphorylation. In addition, depletion of the cells from intracellular calcium does not prevent sorbitol-elicited cPLA(2) phosphorylation, suggesting that this process is independent of the presence of calcium. Together, our results demonstrate that hyperosmotic stress phosphorylates cPLA(2) in human keratinocytes by an EGFR-mediated process.     

First Report of Dragon Fruit (Hylocereus undatus) Anthracnose Caused by Colletotrichum truncatum in China

Anthracnose disease was detected from dragon fruit (Hylocereus undatus) at a market of Yuanjiang County, Yunnan Province, China. The results of pathogenicity test, morphology studies and sequence analyses based on ITS and β‐tubulin loci indicated that the disease was caused by Colletotrichum truncatum. The pathogen produced elliptic, yellow spots with chlorotic halos on the surface of the fruit, and the lesion become depressed gradually. Grey to black acervuli appeared on the lesion surface in concentric circles later. This is the first report of dragon fruit anthracnose caused by this pathogen in China.     

Expression and clinical significance of galectin-3 in osteosarcoma

Galectin-3 is a multifunctional β-galactoside-binding protein which has been shown to play a role in carcinogenesis. However, the involvement of galectin-3 in osteosarcoma remains unclear. In this study, we aimed to examine the serum level of galectin-3 in osteosarcoma patients and healthy controls, and the protein expression of galectin-3 in osteosarcoma tissues and their adjacent non-malignant tissues. We further aimed to investigate the clinical significance of galectin-3 serum and protein expression levels. Galectin-3 serum level was evaluated using ELISA in 132 osteosarcoma patients and 184 healthy controls, while the protein expression of galectin-3 was determined using immunohistochemistry in the malignant and the surrounding non-malignant tissues of the same 132 osteosarcoma patients. Our results showed that the mean galectin-3 serum level was significantly higher in patients than in controls (2.35 ± 0.91 ng/ml vs. 0.86 ± 0.20 ng/ml) (p < 0.0001). Among patients, a higher galectin-3 serum level was significantly associated with the Enneking stage of cancer (p < 0.0001). In addition, we found a significant overrepresentation of high galectin-3 expression in osteosarcoma tissues than in non-malignant tissues (p < 0.0001). Galectin-3 expression in osteosarcoma tissues was also found to be correlated with the Enneking stage of cancer (p < 0.0001) and the occurrence of metastasis (p < 0.0001). In conclusion, galectin-3 could serve as a useful prognostic marker in osteosarcoma.     

Mechanism of action of the tri-hybrid antimicrobial peptide LHP7 from lactoferricin,HP and plectasin on Staphylococcus aureus

The tri-hybrid peptide-LHP7 has the potent activity against Gram-positive and Gram-negative as well as fungi, but its mechanism of action has remained elusive. The effluences of LHP7 on the Staphylococcus aureus cell membrane and targets of intracellular action were investigated. LHP7 exhibited an inhibitory effect on the S. aureus growth, similar to those achieved by plectasin, vancomycin and gramicidin. The membrane integrity studies confirmed that LHP7 disrupted the cell membrane, indicating a membrane permeabilizing killing action. A marginal decline in the intensity fluorescence indicated no significant depolarization of the membrane potential following LHP7 treatment. Furthermore, electron microscopy showed that cell shrinkage, cell wall thickening, cellular content leakage, and cell disruption were observed in the cells treated with LHP7. A gel retardation assay showed that LHP7 bound to the genomic DNA of S. aureus or plasmid DNA at a mass ratio of 2.5–10 (peptide/DNA). Circular dichroism indicated that LHP7 inserted into the groove of DNA. The cell cycle analysis showed that after the treatment with LHP7 for 30 and 60 min, the proportion of cells in I-phase increased from 8.71 to 12.09 % and from 8.71 to 15.68 %, indicating that LHP7 induced arrest of cells in the I-phase. These results would conduce to elucidate its underlying antibacterial mechanism.     

In-depth Proteomics Characterization of Embryogenesis of the Honey Bee Worker (Apis mellifera ligustica)

Identifying proteome changes of honey bee embryogenesis is of prime importance for unraveling the molecular mechanisms that they underlie. However, many proteomic changes during the embryonic period are not well characterized. We analyzed the proteomic alterations over the complete time course of honey bee worker embryogenesis at 24, 48, and 72 h of age, using mass spectrometry-based proteomics, label-free quantitation, and bioinformatics. Of the 1460 proteins identified the embryo of all three ages, the core proteome (proteins shared by the embryos of all three ages, accounting for 40%) was mainly involved in protein synthesis, metabolic energy, development, and molecular transporter, which indicates their centrality in driving embryogenesis. However, embryos at different developmental stages have their own specific proteome and pathway signatures to coordinate and modulate developmental events. The young embryos (<24 h) stronger expression of proteins related to nutrition storage and nucleic acid metabolism may correlate with the cell proliferation occurring at this stage. The middle aged embryos (24–48 h) enhanced expression of proteins associated with cell cycle control, transporters, antioxidant activity, and the cytoskeleton suggest their roles to support rudimentary organogenesis. Among these proteins, the biological pathways of aminoacyl-tRNA biosynthesis, β-alanine metabolism, and protein export are intensively activated in the embryos of middle age. The old embryos (48–72 h) elevated expression of proteins implicated in fatty acid metabolism and morphogenesis indicate their functionality for the formation and development of organs and dorsal closure, in which the biological pathways of fatty acid metabolism and RNA transport are highly activated. These findings add novel understanding to the molecular details of honey bee embryogenesis, in which the programmed activation of the proteome matches with the physiological transition observed during embryogenesis. The identified biological pathways and key node proteins allow for further functional analysis and genetic manipulation for both the honey bee embryos and other eusocial insects.Embryogenesis is an important period during which the body plan of adult honey bees (Apis mellifera L.) is formed. This life stage, lasting 72 h, occurs during the egg laid by the queen before bees hatch as young larva. Worker bees are derived from fertilized eggs and develop through four distinct stages until the imago eventually emerges: egg, larva, pupa, and emerging adult (1–4). The worker is the dominate caste and engages in almost all aspects of social life: taking care of larvae, cleaning the hive, guarding the nest, and foraging for nectar and pollen for the colony. Understanding the developmental mechanism of embryogenesis of honey bee workers at the protein level is conducive to gaining a new insight into honey bee embryology, but information about the mechanisms of honey bee embryos at molecular level is still very limited.The embryo is recognized as an ideal model for genetic modification as compared with larva, pupa, and emerged adults (5). The environment for embryonic development requires a constant temperature of 34 °C and 80% relative humidity, which can easily be simulated under laboratory conditions. In contrast, rearing larvae or pupae is more challenging because they demand a specific temperature, humidity, and nutrition in the colony environment (1, 5). Furthermore, the honey bee has adapted an evolutionary strategy for better colony survival that makes it difficult to rear experimentally modified larvae and pupae within the colony (6, 7), nurse bees use acute judgment to identify and remove abnormal eggs or larvae (8). This adaptation makes raising experimentally treated bees, such as genetically manipulated eggs and larvae, very difficult in the honey bee colony (9–11). Because of totipotency and multiple differentiation potential, modified eggs could be hatched out normally and eventually some of them could be induced to morphologically and physiologically normal adult queens (12), increasing their usefulness as a model system. Moreover, the chorion of honey bee egg is more suitable for puncturing a hole for microinjection as it is much thinner than that of the fruit fly (Drosophila melonogastero) or the silk worm (Bombyx mori) (0.1–0.25 μm for honey bees compared with ∼17 μm for silk worm) (13, 14). These superiorities are quite promising for in vivo transgenic research on honey bee embryos.Until now, a number of genetic manipulations of the honey bee embryo have been developed. For example, embryonic cells in the pre-gastrula stage that have been transplanted with nuclear materials have developed into chimeric honey bee larvae (15). RNA interference (RNAi) has been used for honey bee embryos in vivo to characterize the functioning of specific genes (16) and for genetic effects on morphological differentiation (17, 18). Moreover, the cultivation of short-term (19–21), long-term (22), and immortalized cell lines (23), and the expression of non-Apis genes in cultured embryonic cells (24) have opened up a new era for genetic manipulation of honey bee embryos.Like Drosophila, Apis is a long germ insect in which segmentation occurs across the whole body (25). To date, although several studies have examined morphological change (2, 26, 27) and gene expression (25, 28, 29) during the period of embryogenesis in the honey bee, only a few works report on the preliminary results of the unraveling molecular underpinnings of worker (30) and drone (31) embryogenesis at the proteomic level, identifying only 107 proteins. MS-based proteomics is the primary technology that enables a system-wide view of proteomes and their changes. The development of MS with high resolution, high mass accuracy, and high sequencing speed now allows routine identification and quantification of proteins in a comprehensive and unbiased manner in biological samples with high confidence (32). These technological advances in LC-MS now allow the study of protein expression on a system-wide level (33). Therefore, an in-depth characterization of the proteome changes during the honey bee embryogenesis will provide greater understanding of the molecular mechanisms that underlie the process of embryogenesis in honey bee workers, and offers new insights into the embryology of other social insects.     

Accumulative Characteristics of Some Plant Species to Magnesium around a Magnesite Mine Area in Northeast China

The deposition of Mg-rich dust from magnesite calcination can lead to serious soil contamination. As an efficient remediation method, phytoremediation is often used to remove contaminants from the environment. However, no information is available on phytoremediation of Mg-contaminated soils. In this study, we determined the Mg concentrations in above- and belowground parts of six dominant plant species and soils (0–20 cm layer) beneath these plants in a magnesite mining region in Northeast China. Mg was enriched in leaves of all six species. Translocation factors (TF) of all six species were far greater than 1. Enrichment factors (EF) of Kochia scoparia, Cassia nomame, and Hordeum jubatum were 1.1, 1.1, and 1.0, respectively, while those of the other three species were not greater than 0.5. The results suggest that Kochia scoparia, Cassia nomame, and Hordeum jubatum are the potential Mg-accumulators, and could be used for remediation of Mg-contaminated soils.     

Light Exposure at Night Disrupts Host/Cancer Circadian Regulatory Dynamics: Impact on the Warburg Effect,Lipid Signaling and Tumor Growth Prevention

The central circadian clock within the suprachiasmatic nucleus (SCN) plays an important role in temporally organizing and coordinating many of the processes governing cancer cell proliferation and tumor growth in synchrony with the daily light/dark cycle which may contribute to endogenous cancer prevention. Bioenergetic substrates and molecular intermediates required for building tumor biomass each day are derived from both aerobic glycolysis (Warburg effect) and lipid metabolism. Using tissue-isolated human breast cancer xenografts grown in nude rats, we determined that circulating systemic factors in the host and the Warburg effect, linoleic acid uptake/metabolism and growth signaling activities in the tumor are dynamically regulated, coordinated and integrated within circadian time structure over a 24-hour light/dark cycle by SCN-driven nocturnal pineal production of the anticancer hormone melatonin. Dim light at night (LAN)-induced melatonin suppression disrupts this circadian-regulated host/cancer balance among several important cancer preventative signaling mechanisms, leading to hyperglycemia and hyperinsulinemia in the host and runaway aerobic glycolysis, lipid signaling and proliferative activity in the tumor.