Staffing Up and Dropping Out

Growing public school enrollment and the need to maintain or improve service to students has increased the demand for teachers, perhaps more rapidly than existing sources can accommodate. While some schools recruit well qualified teachers by offering higher salaries or better working conditions, others may satisfy their need for staff by relaxing hiring standards or assigning novice teachers to difficult classrooms. Schools' hiring policies have consequences for student success. Dropout rates tend to be higher where faculties include a greater percentage of minimally educated teachers or teachers with little experience. The relationship between dropout rate and teacher qualifications is independent of student poverty, school size, and location. A proposed strategy to reduce dropout rates is to encourage higher preparation and employment standards, and to provide appropriate classroom assignments, mentoring, and support for new teachers

Christian Apologetics and Modern Thought

Apologeticshttps://digitalcommons.biola.edu/biola-pubs/1011/thumbnail.jp

Unexpected Testing Practices Affecting English Language Learners and Students with Disabilities Under No Child Left Behind

The testing and accountability requirements of the No Child Left Behind Act impose sanctions on schools for not making adequate yearly progress in student achievement. The sanctions may encourage inappropriate practices intended to raise scores of low performing student subgroups. This article considers evidence and consequences of misclassification of English language learners as students with disabilities

1H-NMR investigation of the oxygenation of hemoglobin in intact human red blood cells

Using improved selective excitation methods for protein nuclear magnetic resonance (NMR), we have conducted measurements of the oxygenation of hemoglobin inside intact human red blood cells. The selective excitation methods use pulse shape-insensitive suppression of the water signal, while producing uniform phase excitation in the region of interest and, thus, are suitable for a wide variety of applications in vivo. We have measured the areas of 1H-NMR resonances of the hyperfine-shifted, exchangeable N delta H protons of the proximal histidine residues of the alpha- and beta-chains in deoxyhemoglobin (63 and 76 ppm downfield from the proton resonance of 2,2-dimethyl-2-silapentane-5-sulfonate (DSS), respectively), which are sensitive to the paramagnetic state of the iron, and for which the alpha- and beta-chain resonances are resolved, and from the ring current-shifted gamma 2-CH3 protons of the distal valine residues in oxyhemoglobin (2.4 ppm upfield from DSS), which are sensitive to the conformation of the heme pocket in the oxy state. We have found that the proximal histidine resonances are directly correlated with the degree of oxygenation of hemoglobin, whereas the distal valine resonances appear to be correlated with the conformation in the heme pocket that occurs after the binding of oxygen, in both the presence and absence of 2,3-diphosphoglycerate. In addition, from the proximal histidine resonances, we have observed a preference for the binding of oxygen to the alpha-chain (up to about 10%) of hemoglobin over the beta-chain in both the presence and absence of 2,3-diphosphoglycerate. These new results obtained in intact erythrocytes are consistent with our previous 1H-NMR studies on purified human normal adult hemoglobin. A unique feature of our 1H-NMR method is the ability to monitor the binding of oxygen specifically to the alpha- and beta-chains of hemoglobin both in solution and in intact red blood cells. This information is essential to our understanding of the molecular basis for the hemoglobin molecule serving as the oxygen carrier in vertebrates

In vivo imaging of cytotoxic T cell infiltration and elimination of a solid tumor

Although the immune system evolved to fight infections, it may also attack and destroy solid tumors. In most cases, tumor rejection is initiated by CD8+ cytotoxic T lymphocytes (CTLs), which infiltrate solid tumors, recognize tumor antigens, and kill tumor cells. We use a combination of two-photon intravital microscopy and immunofluorescence on ordered sequential sections to analyze the infiltration and destruction of solid tumors by CTLs. We show that in the periphery of a thymoma growing subcutaneously, activated CTLs migrate with high instantaneous velocities. The CTLs arrest in close contact to tumor cells expressing their cognate antigen. In regions where most tumor cells are dead, CTLs resume migration, sometimes following collagen fibers or blood vessels. CTLs migrating along blood vessels preferentially adopt an elongated morphology. CTLs also infiltrate tumors in depth, but only when the tumor cells express the cognate CTL antigen. In tumors that do not express the cognate antigen, CTL infiltration is restricted to peripheral regions, and lymphocytes neither stop moving nor kill tumor cells. Antigen expression by tumor cells therefore determines both CTL motility within the tumor and profound tumor infiltration

NMRFx Processor: a cross-platform NMR data processing program

NMRFx Processor is a new program for the processing of NMR data. Written in the Java programming language, NMRFx Processor is a cross-platform application and runs on Linux, Mac OS X and Windows operating systems. The application can be run in both a graphical user interface (GUI) mode and from the command line. Processing scripts are written in the Python programming language and executed so that the low-level Java commands are automatically run in parallel on computers with multiple cores or CPUs. Processing scripts can be generated automatically from the parameters of NMR experiments or interactively constructed in the GUI. A wide variety of processing operations are provided, including methods for processing of non-uniformly sampled datasets using iterative soft thresholding. The interactive GUI also enables the use of the program as an educational tool for teaching basic and advanced techniques in NMR data analysis

Zigzag Turning Preference of Freely Crawling Cells

The coordinated motion of a cell is fundamental to many important biological processes such as development, wound healing, and phagocytosis. For eukaryotic cells, such as amoebae or animal cells, the cell motility is based on crawling and involves a complex set of internal biochemical events. A recent study reported very interesting crawling behavior of single cell amoeba: in the absence of an external cue, free amoebae move randomly with a noisy, yet, discernible sequence of ‘run-and-turns’ analogous to the ‘run-and-tumbles’ of swimming bacteria. Interestingly, amoeboid trajectories favor zigzag turns. In other words, the cells bias their crawling by making a turn in the opposite direction to a previous turn. This property enhances the long range directional persistence of the moving trajectories. This study proposes that such a zigzag crawling behavior can be a general property of any crawling cells by demonstrating that 1) microglia, which are the immune cells of the brain, and 2) a simple rule-based model cell, which incorporates the actual biochemistry and mechanics behind cell crawling, both exhibit similar type of crawling behavior. Almost all legged animals walk by alternating their feet. Similarly, all crawling cells appear to move forward by alternating the direction of their movement, even though the regularity and degree of zigzag preference vary from one type to the other