Search Results (36,454)

An open question in radiobiology concerns whether low doses of radiation are harmful or if cells are able to tolerate such exposure with minimal or no disruption. This issue is relevant for evaluating public health risks associated with the increasing number of medical computed tomography (CT) diagnostic procedures. This study evaluated the impact of CT scan-level exposure on human adipose mesenchymal stem cells (hMSCs) by measuring DNA damage responses (γH2AX, 53BP1, pATM foci), proliferation (Ki-67), senescence (β-galactosidase), and multiple gene expressions. Responses to one or five CT exposures were compared to a 2 Gy X-ray dose at intervals from 1 h to 10 passages post-irradiation. It was shown that CT scan briefly increased DNA damage markers but showed no significant long-term effects. A high dose of 2 Gy X-ray exposure caused sustained DNA damage, decreased proliferation, increased senescence, and significant changes in hundreds of genes even after several cell generations. After a single CT exposure, gene expression changes were minimal, while high-dose exposure led to strong activation of DNA repair and stress response pathways. Five CT scans caused a slight activation of LIF and HSPA1B genes, but these effects were minor compared to the high-dose group. All detected effects from CT scans were not observed by ten cell passages, whereas high-dose effects persisted. In conclusion, typical CT scan exposures have only short-term, mild effects on hMSCs, while high-dose radiation causes lasting cellular and genetic changes. Full article

Cysteine-rich polycomb-like protein (CPP) transcription factors (TFs) play critical roles in the process of plant growth and development, as well as stress responses. To date, no reports about CPP TFs have been published for lettuce (Lactuca sativa). In this study, six CPP TFs (LsCPP1-LsCPP6) were identified in lettuce. Phylogenetic analysis showed that LsCPP TFs were classified into two clades (Clade I and Clade II). Six LsCPP genes were distributed across four chromosomes. Cis-elements, which are involved in environmental stress, hormone response, and development processes, were identified in the promoters of LsCPP genes. LsCPP genes were induced by different tissues and the stem enlargement processes of stem lettuce. Plant hormones (SA, ABA) and abiotic stress (salt, drought) induced the expression of LsCPP genes. LsCPP4 was significantly induced after drought stress for 12 h. Notably, the expression level of LsCPP4 increased more than 10 times (12 h) and 150 times (24 h) after salt stress. ABA and SA significantly induced the expression profile of LsCPP6. This study not only provides the basis for future functional research of LsCPP genes, particularly their roles in lettuce stress resistance, but also provides a foundation for molecular breeding to enhance the agricultural traits in lettuce. Full article

Salt stress severely constrains agricultural productivity in arid and semi-arid regions. This study evaluated exogenous proline as an osmoprotector in Physalis ixocarpa Brot. (Mexican husk tomato) under salinity. Germination screening identified 75 mM NaCl as a threshold stress level, reducing germination by 38.9% while maintaining seedling viability. Proline pretreatment (30-min imbibition) at 8 mM restored germination to 78% and fresh weight to control levels under salt stress. In vitro experiments revealed that 8 mM proline enhanced chlorophyll content above salt-stressed controls while reducing root length from 9.72 to 5.08 cm, indicating resource reallocation toward photosynthetic protection. Infrared spectroscopy showed characteristic polysaccharide shifts and bands potentially associated with proline incorporation. Gas chromatography–mass spectrometry metabolomics of stem–leaf extracts revealed salt-induced synthesis of nitrogenous osmolytes (such as long-chain amines) and carbohydrate reorganization from α-D-glucopyranoside to β-D-riboside. Proline treatment restored the original carbohydrate profile while generating pyrrolidine derivatives (2.83%), evidence of active proline metabolism. Phenolic antioxidants (e.g., catechol) present in controls were absent under both salt stress and proline treatment, suggesting that proline’s protective mechanism may operate through metabolic regulation of osmolyte pathways and membrane stabilization rather than inducing phenolic antioxidant synthesis. These findings demonstrate proline’s multifaceted protective mechanisms and support its potential application for enhancing salt tolerance in this crop. Full article

Salt stress is a major constraint on cowpea cultivation in semi-arid regions, primarily due to excess salts in irrigation water and soils. We aimed to investigate the effects of foliar magnesium (Mg) application on the production, phenology, and seed vigor of the cowpea landraces “Pingo de Ouro” and “Costela de Vaca” under salt stress conditions. Two experiments were conducted. The first was carried out in a greenhouse using a randomized block design with five replicates, in a 2 × 3 × 4 factorial scheme: two cowpea landraces (“Pingo de Ouro” and “Costela de Vaca”), three irrigation water salinity levels (0.54, 3.50, and 5.00 dS m⁻¹), and four foliar doses of a product (0.0, 1.0, 2.0 and 3.0 mL L⁻¹) containing 8% magnesium. Morphological traits and seed production were evaluated. The second experiment was conducted in a laboratory using a completely randomized design, also in a 2 × 3 × 4 factorial, with four replicates of 25 seeds each. In the first experiment, the 1 mL L⁻¹ dose provided the best results for pod length in the variety “Pingo de Ouro” under an electrical conductivity salinity of 5.00 dS m⁻¹. In the variety “Costela de Vaca”, this same dose increased the number of seeds per pod and the 100-seed weight under the same salinity level. In the second experiment, seedlings of “Pingo de Ouro” grown from seeds produced by plants treated with 2 and 3 mL L⁻¹ doses showed greater shoot length, root length, stem diameter, and shoot fresh mass, particularly under 0.54 dS m⁻¹ salinity. Therefore, “Pingo de Ouro” exhibited superior seedling growth at doses of 2 and 3 mL L⁻¹, particularly under conditions of low salinity. These findings support the use of foliar magnesium fertilization as an effective agronomic strategy to enhance seed production and quality in cowpea landraces under salt stress conditions. Full article

Botryosphaeria dothidea (Moug. ex Fr.) Ces. & De Not. is a major pathogenic fungus causing stem canker in Idesia polycarpa, posing a significant threat to the growth and survival of its plantations. To elucidate the physiological and biochemical responses of the host under pathogenic stress, this study used two-year-old potted seedlings of I. polycarpa (provenance: ‘Emeishan No. 1’) and conducted artificial inoculation. Dynamic changes in physiological and biochemical indices at different disease stages were systematically monitored. The results revealed a distinct stage-specific response pattern: in the early infection stage, the activities of antioxidant enzymes (POD and SOD) increased rapidly, accompanied by significant elevations in osmotic regulators such as proline and soluble protein. In the mid-stage, malondialdehyde (MDA) content increased, while the levels of photosynthetic pigments—especially chlorophyll b and carotenoids—declined, indicating intensified oxidative damage. In the late stage, antioxidant capacity and osmotic adjustment weakened, and the photosynthetic system was continuously impaired. Correlation analysis further demonstrated significant synergistic relationships among antioxidant defense, membrane stability, osmotic regulation, and photosynthetic function. These findings enhance our understanding of the disease resistance mechanisms in I. polycarpa and provide a theoretical and practical reference for resistance evaluation and precise management of canker disease in woody species. Full article

A complex and gradual process, the epithelial–mesenchymal transition (EMT) occurs both during embryonic development and tumor progression. Cells undergo a transition from an epithelial to a mesenchymal state throughout this process. More and more evidence points to EMT as a cause of increased metastatic spread of prostate cancer (PCa), along with stemness enhancement and therapy resistance. Here, we used bioinformatic methods to analyze gene expression microarray data, single-cell RNA sequencing, oncogenes, and tumor suppressor genes (TSGs) in order to reconstruct the network of differentially expressed genes (DEGs) involved in the epithelial–mesenchymal transition with PCa. No prior study has documented this sort of analysis. We next validated our results using data from the Cancer Genome Atlas (TCGA), which included microarray and single-cell RNA sequencing. Potentially useful in PCa diagnosis and treatment are extracellular matrix in epithelial–mesenchymal transition genes, including ITGBL1, DSC3, COL4A6, ANGPT1, ARMCX1, MICAL2, and EPHA5. In this study, we aimed to shed light on the molecular characteristics and pathways of DEGs in PCa, as well as to identify possible biomarkers that are important in the development and advancement of this cancer. These insights have important implications for understanding prostate cancer progression and for the development of therapeutic strategies targeting ECM-mediated pathways. Full article

The unique ability of oncolytic viruses (OVs) to replicate in and destroy malignant cells while leaving healthy cells intact and activating the host immune response makes them powerful targeted anti-cancer therapeutic agents. Vesicular stomatitis virus (VSV) only causes mild and asymptomatic infection, lacks pre-existing immunity, can be genetically engineered for enhanced efficiency and improved safety, and has a broad cell tropism. VSV can facilitate targeted delivery of immunostimulatory cytokines for an enhanced immune response against cancer cells, thus decreasing the possible toxicity frequently observed as a result of systemic delivery. In this study, the oncolytic potency of the two rVSV versions, rVSV-dM51-GFP, delivering green fluorescent protein (GFP), and rVSV-dM51-mIL12-mGMCSF, delivering mouse interleukin-12 (mIL-12) and granulocyte-macrophage colony-stimulating factor (mGMCSF), was compared on the four murine cancer cell lines of different origin and healthy mesenchymal stem cells (MSCs) at 24 h post-infection by flow cytometry. Lewis lung carcinoma (LL/2) cells were demonstrated to be more susceptible to the lytic effects of both rVSV versions compared to melanoma (B16-F10) cells. Detection of expression levels of antiviral and pro-apoptotic genes in response to the rVSV-dM51-GFP infection by quantitative PCR (qPCR) showed lower levels of IFIT, RIG-I, and N-cadherin and higher levels of IFNβ and p53 in LL/2 cells. Subsequently, C57BL/6 mice, infused subcutaneously with the LL/2 cells, were injected intratumorally with the rVSV-dM51-mIL12-mGMCSF 7 days later to assess the synergistic effect of rVSV and immunostimulatory factors. The in vivo study demonstrated that treatment with two rVSV-dM51-mIL12-mGMCSF doses 3 days apart resulted in a tumor growth inhibition index (TGII) of over 50%. Full article

The heavy reliance of the mushroom industry on sawdust substrates is putting increasing pressure on already limited forest resources, forcing researchers to seek alternative materials. This study investigated the feasibility of using post-harvest djulis (Chenopodium formosanum Koidz.) stems, waste from this indigenous crop in Taiwan, to partially replace sawdust for Pleurotus sajor-caju cultivation. Initial screening with 0–100% djulis replacement revealed growth inhibition above 50% incorporation levels. Refined experiments focusing on 0–30% djulis ratios demonstrated that strain PT exhibited superior adaptation to djulis-containing substrates. Commercial scale grow bag trials showed that among djulis treatments, 25% djulis incorporation achieved the fastest mycelial colonization rate (1.0 cm/day), while 15% incorporation yielded the highest biological efficiency (76.17%), comparable to commercial controls (76.80%). Three-flush harvest cycles confirmed stable productivity across treatments, with total yields ranging from 286 to 320 g/bag. Nutritional analysis showed no major changes in amino acids and antioxidants, with djulis incorporation maintaining protein quality while some enhancement in total free amino acid content and reducing power at 25% incorporation. These findings demonstrate that 15–25% djulis stem substitution sustained commercial production parameters while contributing to sustainable agricultural waste management and reducing forest resource dependence. Full article

This paper reviews two solid-state NMR approaches for investigating mobile molecules in nanoporous materials, with a focus on the motion-averaged dipole–dipole interactions of nuclear spins. The first approach addresses intramolecular dipole–dipole interactions, where the anisotropic molecular motion in solids leads to partially averaged interactions that reflect the spatial distribution of molecular positions during motion. The second approach examines intermolecular dipole–dipole interactions, which produce anisotropic features in NMR spectra and affect nuclear spin relaxation due to the Brownian motion of molecules within non-spherical nanoscale pores. The applicability of these methods is considered for systems exhibiting molecular mobility, including zeolites, collagen tissues, intercalation compounds, and plant stems. Full article

The lotus (Nelumbo nucifera Gaertn.) is an ornamental aquatic plant, highly valued in Asian cultures for its religious symbolism, culinary uses, and medicinal properties. However, the lotus exhibits low genetic diversity in nature, which limits the genetic resources available for breeding programs. Gamma irradiation is an effective method for inducing genetic variation in lotus breeding. The present study examines the gamma sensitivity of lotus seedlings, along with the morphological and anatomical changes induced by various gamma dosages. The results showed that high-dose gamma irradiation (≥100 Gy) significantly inhibited seedling growth and altered most anatomical parameters, each exhibiting distinct dose–response patterns except for midrib diameter. The 100 Gy treatment resulted in the maximum stem diameter, while root diameter peaked at 500 Gy, and the highest dose (600 Gy) produced the largest petioles. Gamma irradiation also triggered tannin accumulation and reduced aerenchyma formation in the leaves. The obtained results demonstrate organ-specific responses to gamma irradiation in the lotus, with leaves being the most sensitive, while petioles, stems, and roots exhibited more variable dose-dependent effects. Full article

Viral infection is a significant cause of morbidity and mortality following allogeneic hematopoietic stem cell transplantation (Allo-HSCT), largely due to its impact on and interaction with immune reconstitution. Both innate and adaptive immunity are essential for effective viral control, yet their recovery post-transplant is often delayed or functionally impaired. Emerging evidence suggests genetic variation, particularly polymorphisms in the IL28B gene (encoding IFN-λ3), as a critical factor influencing the quality and timing of immune responses during the early post-transplant period. This review explores the role of IL28B polymorphisms in shaping antiviral immunity, in general, as well as after Allo-HSCT. IL28B variants have been implicated in modulating interferon-stimulated gene (ISG) expression, natural killer (NK) cell activity, and type I/III interferon signaling, all central components of innate immune defense against viral infections. Furthermore, IL28B polymorphisms, particularly rs12979860, have been shown in both general populations and limited HSCT cohorts to alter T cell response and interferon production, affecting reactivation and clearance of multiple viruses such as cytomegalovirus (CMV), hepatitis B virus (HBV), hepatitis C virus (HCV), Epstein–Barr virus (EBV), COVID-19, and BK polyomavirus (BKPyV) as well as Graft vs. Host disease, thereby affecting adaptive immune reconstitution and long-term viral control. Understanding how IL28B genotype alters immune dynamics in transplant recipients could enhance risk stratification for CMV and other diseases and inform personalized prophylactic or therapeutic strategies. Therefore, this review highlights IL28B as a promising biomarker and potential immunoregulatory target in the management of viral infection post-Allo-HSCT. Full article

Background: The intestinal tract is a host to a high number of diverse bacteria, and the presence of multidrug-resistant (MDR) Enterobacterales strains acts as a reservoir and a source of infection. The interactions between the intestinal microbiome and colonizer Enterobacterales strains influence long-lasting colonization. Aims: In this narrative review, we summarize available data about the intestinal colonization of MDR Enterobacterales strains and correlations between colonization and the intestinal microbiome. Results: Several endogenous and exogenous factors influence the intestinal colonization of MDR Enterobacterales strains. On the gut microbiome level, the intestinal microbial community is composed of the Lachnospiraceae family (e.g., Lachnoclostridium, Agathobacter, Roseburia, Tyzzerella), which indicates a protective role against colonizer MDR Enterobacterales strains; by contrast, a high abundance of Enterobacterales correlates with the colonization of MDR Enterobacterales strains. In specific patient groups, striking differences in microbiome composition can be detected. Among hematopoietic stem-cell-transplanted patients colonized by extended-spectrum beta-lactamase (ESBL)-producing Enterobacterales, a greater abundance of Bifidobacterium, Blautia, Clostridium, Coprococcus, L-Ruminococcus, Mogibacteriaceae, Peptostreptococceae and Oscillospira was observed compared to patients not colonized by ESBL-producing strains, who had a greater abundance of Actinomycetales. In liver transplant patients, a reduction in the alpha-diversity of the intestinal microbiome in fecal samples correlates with the carriage of MDR Enterobacterales. Conclusions: Intestinal colonization with MDR Enterobacterales is a multifactorial process that involves the MDR strain (e.g., its plasmids, fimbria), host and mucosal factors (e.g., IgA and defensin) and exogenous factors (e.g., use of antibiotics, hospitalization). On the gut microbiome level, the Lachnospiraceae family is dominant among intestines not colonized by MDR strains, but a high abundance of Enterobacterales was correlated with colonization with MDR Enterobacterales strains. Full article

In this paper, Nanocnide simingshanensis is described as a new species based on morphological and molecular analyses, and its taxonomic relationships are discussed. The new species is currently known only from the Siming Mountain region of Yuyao County and the Yaolin National Forest Park of Tonglu County, both in Zhejiang Province, eastern China, where it grows in shrubs at an elevation of about 650 m under deciduous broad-leaved forests and at a limestone cave entrance. Morphological analysis strongly supports that N. simingshanensis should be classified into the genus Nanocnide. This species is distinguished from the related species N. pilosa and N. lobata by having long straight hirsute hairs perpendicular to the stem, petioles and peduncles, longer petioles, larger leaf blades, and female inflorescences developing on branchlets. It differs from N. zhejiangensis and N. japonica by having glomerulate male inflorescences shorter than leaves (vs. cymose inflorescences longer than leaves). Nuclear ribosomal DNA internal transcribed spacer (ITS) phylogenetic analysis demonstrates that N. pilosa and N. lobata are the closest extant relatives to the new species. Full article

The fungicides oxathiapiprolin, benthiavalicarb, and their mixture (Zorvec Endavia) provided excellent protection for tomato fruits against Phytophthora infestans when applied directly to the fruits or to the fruit stem scar. High levels of protection were also recorded when the fungicides were applied to the root system of fruit-bearing plants grown in a greenhouse. The objective of this study was to follow the translocation of oxathiapiprolin and benthiavalicarb into the fruits of tomato. We discovered that while soil drenching conferred strong protection to leaves, it failed to provide good protection for the fruits. Similarly, a fungicidal spray applied to plants while their fruits were bagged during spraying provided full protection to the leaves but failed to protect the fruits. These results indicate differential systemic translocation of the fungicides to leaves versus fruits. LC–MS/MS analyses revealed translocation of oxathiapiprolin and benthiavalicarb to leaves but not to fruits in soil-treated plants. Thus, while fruits may be less protected, they may also pose a lower risk of pesticide residues to consumers. This is the first study to compare fruit versus leaf infection and demonstrate differential systemic translocation of systemic fungicides to leaves versus fruits. Full article

The infestation of boktor (Xystrocera festiva Pascoe) stem borer in Sengon (Falcataria falcata) tree plantations in Indonesia, especially in Java, has caused severe losses by damaging the stems, decreasing wood quality, and potentially leading to mortality. To digest the woods, the X. festiva larvae’s gut has at least two digestive enzymes, which are trypsin and α-amylase. Former studies have shown that F. falcata produces inhibitors of these two enzymes as part of its defense mechanisms. This research aimed to analyze trypsin inhibitor (TI) and α-amylase inhibitor (AAI) transcripts, as well as their expression, in X. festiva-infested and resistant F. falcata trees. We found 19 contigs encoding the TI gene and 29 contigs encoding AAI. The results were able to predict the sequence of the DNA that produced the TI and AAI transcriptomes, which proved that one gene could be expressed differently due to alternative splicing. The DEG analysis and RT-PCR confirmed that mostly the TI and AAI activity was heavily induced by the X. festiva larvae attacks. The expression of the TI gene was upregulated 0.78 times, while the AAI gene expression was upregulated 2.44 times in infested samples. The findings from this study are fundamental in understanding the mechanism of F. falcata resistance against X. festiva infestation and selecting the resistant trees. Full article