Comptonlindsey9106

The fungus also increased aboveground biomass and changed several root architectural traits, but only under low soil moisture conditions, indicating a reduction in benefits of the mycorrhizal association under high soil moisture. Results from this study indicate that an arbuscular mycorrhizal fungus can increase some key measures of plant growth and cell wall chemistry regardless of soil moisture conditions but is most beneficial in low soil moisture conditions.Rare earth elements including samarium have been widely used in modern technologies in recent decades. Following over-exploitation and soil contamination, they can accumulate in plants and be toxic at high concentrations. Arbuscular mycorrhizae benefit plants in metal-contaminated soils by improving their survival and growth and alleviating metal toxicity, but little information is available about soil contaminated by rare earth elements. We performed two experiments using samarium to study the role of arbuscular mycorrhizal fungi on plant growth and samarium transfer to alfalfa in a samarium-spiked soil. A pot experiment was conducted in a soil spiked with two concentrations of samarium and a non-spiked control, inoculated or not with a metal-tolerant Funneliformis mosseae. A compartmented pot experiment was then performed with a separated compartment containing samarium-spiked sand only accessible by F. mosseae fungal hyphae to further study the transport of samarium from the soil to alfalfa. The biomass of alfalfa grown on samarium-spiked soil was reduced, while it was significantly higher following arbuscular mycorrhiza inoculation in the pot experiment, both in the control and samarium-spiked soil. Although mycorrhizal plants had a higher phosphorus content than non-mycorrhizal ones, there was no significant difference in samarium concentrations between mycorrhizal and non-mycorrhizal plants. The compartment experiment confirmed that there was no significant samarium transfer to the plant by F. mosseae. Other fungi and plants should be tested, and field experiments performed, but our results suggest that arbuscular mycorrhizal plants might be considered in phytorestoration of rare-earth-contaminated soils.Entoloma clypeatum species complex (ECSC) forms ectomycorrhiza-like roots (EMLR) with host plant species of Rosaceae or Ulmaceae. The EMLR colonized with ECSC are characterized by a thick fungal mantle, absence of a Hartig net structure, and collapse of the apical meristem caused by hyphal invasion. Some researchers have suggested parasitism of ECSC because of this unique mode of colonization; however, the nature of the interaction between ECSC and host plants has not been investigated in co-culture because of the difficulty of culturing this group of fungi. We established a procedure to synthesize EMLR of ECSC on pear seedlings using fungal cultures. Three conspecific strains of ECSC isolated from basidiospores and one strain isolated from EMLR were tested. Cultured mycelia were inoculated onto a modified Norkrans' C (MNC) or Hyponex-yeast-glucose (HYG) medium slant on the bottom of a polycarbonate jar and covered with autoclaved andosol or a vermiculite/sphagnum moss mixture (VSM); an axenically cultivated Pyrus betulifolia seedling was then planted in the jar. Five months after inoculation, the formation of EMLR with Hartig net-like hyphae was confirmed in all of the experimental plots. However, the rate of root colonization was significantly higher in experimental plots using andosol than in those using VSM. The growth of pear seedlings was similar irrespective of the level of root colonization, suggesting commensalism rather than parasitism of ECSC. One experimental plot using strain A3, an MNC slant, and andosol as a substrate produced ECSC fruiting bodies with mature basidia and basidiospores. The results suggested that our procedure enables the synthesis of EMLR of ECSC and cultivation of their fruiting bodies.To adapt to changing environments cells must signal and signaling requires messengers whose concentration varies with time in space. We here consider the messenger role of calcium ions implicated in regulation of the wave-like bending dynamics of cilia and flagella. The emphasis is on microtubules as polyelectrolytes serving as transmission lines for the flow of Ca2+ signals in the axoneme. This signaling is superimposed with a geometric clutch mechanism for the regulation of flagella bending dynamics and our modeling produces results in agreement with experimental data.Gliomas have substantial mortality to incidence rate ratio and a dismal clinical course. Newer molecular insights, therefore, are imperative to refine glioma diagnosis, prognosis and therapy. Meningioma 1 (MN1) gene is a transcriptional co-regulator implicated in other malignancies, albeit its significance in glioma pathology remains to be explored. IGFBP5 is regulated transcriptionally by MN1 and IGF1 and is associated with higher glioma grade and shorter survival time, prompting us to ascertain their correlation in these tumors. We quantified the expression of MN1, IGFBP5 and IGF1 in 40 glioma samples and examined their interrelatedness. MN1 mRNA-protein inter-correlation and the gene's copy number were evaluated in these tumors. Publicly available TCGA datasets were used to examine the association of MN1 expression levels with patient survival and for validating our findings. We observed MN1 overexpression correlated with low-grade (LGGs) and not high-grade gliomas and is not determined by the copy number alteration of the gene. selleck chemical Notably, gliomas with upregulated MN1 have better overall survival (OS) and progression-free survival (PFS). IGFBP5 expression associated inversely with MN1 expression levels in gliomas but correlated positively with IGF1 expression in only LGGs. This suggests a potential grade-specific interplay between repressive and activating roles of MN1 and IGF1, respectively, in the regulation of IGFBP5. Thus, MN1 overexpression, a promising predictor of OS and PFS in gliomas, may serve as a prognostic biomarker in clinical practice to categorize patients with survival advantage.