Optimizing Blood Culture Volumes by Implementing PDCA Cycle Management.

Background: The aim of this study was to optimize the mean volume of blood drawn by nurses to a level that is recommended by our hospital through the implementation of PDCA cycle management. The purpose of the current study was to match the mean volumes of blood drawn with the volume recommended by the manufacturer.

Methods: The adequacy of blood volume in a bottle of aerobic blood culture per venipuncture was evaluated for every month from January 2021 to March 2022 by using the Becton Dickinson BD blood volume monitoring system.

The Impact of Phosphorus on Plant Immunity.

Phosphorus (P) is the second most essential macronutrient in terms of limiting plant growth. The genes involved in P acquisition, transport, storage, utilization and respective regulation have been extensively studied. In addition, significant attention has been given to the crosstalk between P and other environmental stresses.

Structure-Function Analysis Reveals Amino Acid Residues of Phosphate Transporter PHT1;1 Crucial for Its Activity.

Phosphorus (P), an essential plant macronutrient, is acquired in the form of inorganic phosphate (Pi) by transporters located at the plasma membrane of root cells. To decipher the Pi transport mechanism, Pi transporter 1;1 (PHT1;1), the most predominantly H-coupled Pi co-transporter in the root, was selected for structure-function analysis. We first predicted its secondary and tertiary structures on the basis of the Pi transporter (PT) and identified 28 amino acid residues potentially engaged in the activity of PHT1;1.

Potassium Stimulation of IAA Transport Mediated by the Arabidopsis Importer AUX1 Investigated in a Heterologous Yeast System.

Auxin regulates diverse processes involved in plant growth and development. AUX1 is the first identified and most widely investigated auxin importer, and plays an important role in root gravitropism and the development of lateral root and root hair. However, the regulation of auxin transport by AUX1 is still not well understood.

Regulation of H-pyrophosphatase by 14-3-3 Proteins from Arabidopsis thaliana.

Plant vacuolar H-transporting inorganic pyrophosphatase (V-PPase; EC 3.6.1.

Phosphate deficiency-induced cell wall remodeling: linking gene networks with polysaccharide meshworks.

The formation of root hairs is a unique developmental process that requires the concerted action of a multitude of proteins. Root hair development is controlled by intrinsic programs, but fine-tuning of these programs occurs in response to environmental signals, dictating the shape and function of epidermal cells. In particular, low availability of soil-immobile mineral nutrients such as phosphate (Pi) affects the density and length of root hairs, resulting in an increased absorptive surface area.

Coexpression-based clustering of Arabidopsis root genes predicts functional modules in early phosphate deficiency signaling.

Phosphate (Pi) deficiency triggers the differential expression of a large set of genes, which communally adapt the plant to low Pi bioavailability. To infer functional modules in early transcriptional responses to Pi deficiency, we conducted time-course microarray experiments and subsequent coexpression-based clustering of Pi-responsive genes by pairwise comparison of genes against a customized database. Three major clusters, enriched in genes putatively functioning in transcriptional regulation, root hair formation, and developmental adaptations, were predicted from this analysis.