Promotion of importin alpha-mediated nuclear import by the phosphorylation-dependent binding of cargo protein to 14-3-3

14-3-3 proteins are phosphoserine/threonine-binding proteins that play important roles in many regulatory processes, including intracellular protein targeting. 14-3-3 proteins can anchor target proteins in the cytoplasm and in the nucleus or can mediate their nuclear export. So far, no role for 14-3-3 in mediating nuclear import has been described. There is also mounting evidence that nuclear import is regulated by the phosphorylation of cargo proteins, but the underlying mechanism remains elusive. Myopodin is a dual-compartment, actin-bundling protein that functions as a tumor suppressor in human bladder cancer. In muscle cells, myopodin redistributes between the nucleus and the cytoplasm in a differentiation-dependent and stress-induced fashion. We show that importin alpha binding and the subsequent nuclear import of myopodin are regulated by the serine/threonine phosphorylation-dependent binding of myopodin to 14-3-3. These results establish a novel paradigm for the promotion of nuclear import by 14-3-3 binding. They provide a molecular explanation for the phosphorylation-dependent nuclear import of nuclear localization signal-containing cargo proteins.     

Cyclic nucleotide phosphodiesterase and protein activator in fetal rabbit tissues.

Cyclic nucleotide phosphodiesterase activity (EC 3.1.4.17) was studied in fetal and newborn rabbit brain, heart, liver, kidney, and lung. Kinetic analysis of phosphodiesterase activity from homogenates of organs from the 25-day embryo suggested the presence of a high K_m and a low K_m activity for both cyclic AMP and cyclic GMP hydrolysis. The addition of 1 μm cyclic GMP to the assay stimulated the hydrolysis of cyclic AMP by whole homogenates of liver, brain, lung, and kidney, but not heart, at all of the ages studied. The addition of micromolar levels of calcium ion stimulated cyclic GMP hydrolysis by homogenates of fetal brain, heart, and kidney, with or without added protein activator. Cyclic GMP phosphodiesterase activity was not stimulated by the addition of calcium ion in homogenates of early fetal rabbit liver and lung, but stimulation was detected in the late embryo and newborn. The presence of the heat-stable protein activator was demonstrated in brain, heart, kidney, liver, and lung tissue at all of the fetal ages studied, and in the newborn rabbit. DEAE-cellulose chromatography demonstrated the presence of three separable enzymes in brain and liver at 15 days, heart at 19 days, and lung and kidney at 25 days of gestation, with no changes in the kinetic properties of the isolated enzymes during development. These experiments suggest that all of the organs studied have the mature array of phosphodiesterases early in development, but an enzyme from liver and lung becomes sensitive to regulatory control by calcium only late in gestation.     

GPR56 Functions Together with α3β1 Integrin in Regulating Cerebral Cortical Development

Loss of function mutations in GPR56, which encodes a G protein-coupled receptor, cause a specific human brain malformation called bilateral frontoparietal polymicrogyria (BFPP). Studies from BFPP postmortem brain tissue and Gpr56 knockout mice have previously showed that GPR56 deletion leads to breaches in the pial basement membrane (BM) and neuronal ectopias during cerebral cortical development. Since α3β1 integrin also plays a role in pial BM assembly and maintenance, we evaluated whether it functions together with GPR56 in regulating the same developmental process. We reveal that loss of α3 integrin enhances the cortical phenotype associated with Gpr56 deletion, and that neuronal overmigration through a breached pial BM occurs earlier in double knockout than in Gpr56 single knockout mice. These observations provide compelling evidence of the synergism of GPR56 and α3β1 integrin in regulating the development of cerebral cortex.     

NODE COUNTING IN AXILLARY BUDS OF NICOTIANA TABACUM CV. WISCONSIN 38, A DAY-NEUTRAL PLANT

A mature, quiescent, primary axillary bud on the main axis of a flowering Nicotiana tabacum cv. Wisconsin 38 plant, when released from apical dominance and before forming its terminal flower, produced a number of nodes which was dependent upon its position on the main axis. Each bud produced about one more node than the next bud above it. The total number of nodes produced by an axillary bud was about 6 to 8 greater than the number of nodes present above this bud on the main axis. At anthesis of the terminal flower on the main axis, mature, quiescent, primary axillary buds had initiated 7 to 9 leaf primordia while secondary axillary buds, sometimes present in addition to the primary ones, had initiated 4 to 5 leaf primordia. When permitted to grow out independently, primary and secondary axillary buds located at the same node on the main axis produced the same number of nodes before forming their terminal flowers. In contrast, immature primary axillary buds which had produced only 5 leaf primordia and which were released from apical dominance prior to the formation of flowers on the main axis produced only as many nodes as would be produced above them on the main axis by the terminal meristem, i.e., “extra” nodes were not produced. Therefore, it is the physiological status of the plant and not the number of nodes on the bud at the time of release from apical dominance that influenced the node-counting process of a bud. When two axillary buds were permitted to develop on the same main axis, each produced the same number of nodes as single axillary buds developing at these nodes. Thus, the counting process in an axillary bud of tobacco is independent of other buds. Axillary buds on main axes of plants that had been placed horizontally produced the same number of nodes as identically-positioned axillary buds on vertical plants, indicating that gravity does not play a major role in the counting, by an axillary bud, of the nodes on the main axis.     

The relationship between antigen concentration, antigen internalization, and antigenic complexes: modeling insights into antigen processing and presentation

Native antigen is processed and subsequently presented on the surface of antigen-presenting cells, an important step in the elicitation of an immune response. The early events of antigen processing and presentation include: ingestion of a native antigen, intracellular degradation to expose an antigenic peptide fragment, binding of this fragment with an MHC class II molecule, and display of this newly formed complex on the cell surface. Through the development of a mathematical model, a set of mathematical equations which describes the time-dependent appearance, disappearance, and movement of individual molecules, quantitative insight can be gained into the pathways and rate-limiting steps of antigen presentation. The credibility of the model has been verified by comparison to literature data. For example, it has been shown experimentally that macrophages require 60 min for effective antigen presentation, whereas B cells require 6-8 h. The mathematical model predicts these presentation times and identifies the difference in the cell's respective pinocytic rates and sizes as important parameters. B cells capture antigen in their environment through nonspecific fluid-phase pinocytosis as well as by binding antigen to their surface immunoglobulin, allowing receptor-mediated uptake. Uptake of antigen via receptor-mediated endocytosis has been reported to require 1,000-fold less antigen than uptake via nonspecific pinocytosis. The mathematical model clearly predicts this decrease in concentration. The model also makes quantitative predictions for the number of MHC class II-antigen complexes needed to produce T cell stimulation.     

Regulation of Succinate Dehydrogenase in Higher Plants: II. Activation by Substrates, Reduced Coenzyme Q, Nucleotides, and Anions

The effect of various agents on the activation of succinate dehydrogenase in cauliflower (Brassica oleracea) and mung bean (Phaseolus aureus) mitochondria and in sonicated particles has been investigated. Reduced coenzyme Q₁₀, inosine diphosphate, inosine triphosphate, acid pH, and anions activate the enzyme in mitochondria from higher plants in the same manner as in mammalian preparations. Significant differences have been detected in the behavior of plant and animal preparations in the effects of ATP, ADP, NADH, NAD-linked substrates, and of 2, 4-dinitrophenol on the state of activation of the dehydrogenase. In mammalian mitochondria ATP activates, whereas ADP does not, and the ATP effect is shown only in intact mitochondria. In mung bean and cauliflower mitochondria, both ATP and ADP activate and the effect is also shown in sonicated and frozen-thawed preparations. In sonicated mung bean mitochondria NADH causes complete activation, as in mammalian submitochondrial particles, but in sonicated cauliflower mitochondria activation by NADH is incomplete, as is also true of intact, anaerobic cauliflower mitochondria. Moreover, neither NAD-linked substrates nor a combination of these with NADH can fully activate the enzyme in cauliflower mitochondria. In contrast to mammalian mitochondria, succinate dehydrogenase is not deactivated in cauliflower or mung beam mitochondria under the oxidized conditions brought about by uncoupling of oxidative phosphorylation by 2,4-dinitrophenol.