Immunocytochemical localization and ontogenic development of α-melanocyte-stimulating hormone (α-MSH) in the brain of a pleuronectiform fish,barfin flounder

-Melanocyte-stimulating hormone (-MSH) is a pituitary hormone derived by post-translational processing from proopiomelanocortin and is involved in background adaptation in teleost fish. It has also been reported to suppress food intake in mammals. Here, we examined the immunocytochemical localization of -MSH in the brain and pituitary of a pleuronectiform fish, the barfin flounder (Verasper moseri), as a first step in unraveling the possible function of -MSH in the brain. The ontogenic development of the -MSH system was also studied. In the pituitary, -MSH-immunoreactive (ir) cells were preferentially detected in the pars intermedia. In the brain, -MSH-ir neuronal somata were located in the nucleus tuberis lateralis of the basal hypothalamus, and -MSH-ir fibers were located mainly in the telencephalon, hypothalamus, and midbrain. -MSH-ir neuronal somata did not project their axons to the pituitary. The -MSH-ir neurons differed from those immunoreactive to melanin-concentrating hormone. -MSH cells in the pituitary and -MSH-ir neuronal somata in the brain were first detected 1 day and 5 days after hatching, respectively. The distribution of -MSH-ir cells, neuronal somata, and fibers showed a pattern similar to that in adult fish 30 days after hatching. These results indicate that the functions of -MSH in the brain and pituitary are different and that -MSH plays physiological roles in the early development of the barfin flounder. This study was supported in part by grants from the Regional Science Promotion Program Evolutional Research of the Japan Science and Technology Corporation, and the Yumekendo-Iwate Research and Promotion Project of the Iwate Prefectural Government Science and Technology Division to A.T.     

Influence of amylose,amylopectin and pullulan on β-glucuronidase activity of starch-degrading Escherichia coli

Synthesis of -glucuronidase in starch-degrading Escherichia coli (S1) was induced by amylose, amylopectin and pullulan supplied in mineral medium as the sole carbon source (1%, w/v). The maximum activity occurred after 4 days when cultures reached the stationary phase of growth, but induction was also evident during log-phase. The effects obtained with amylose, amylopectin and pullulan were higher than that obtained with maize starch.     

Inhibition of 5′-nucleotidase by concanavalin A: Evidence for localization on the outer surface of the plasma membrane

Summary 5-Nucleotidase activity of rat liver plasma membrane is markedly inhibited by concanavalin A. Taken together with a unilateral pattern of labelling of concanavalin A binding sites with hemocyanin, the results indicate that an allosteric site of the enzyme is at the outer surface of the membrane.Work supported in part by NIH CA 13145 to D.J. Morré and by U.S. NASA W-12792(05) to J. Shen-Miller. Argonne National Laboratory is operated under the auspices of the U.S. Energy Research and Development Administration. We thank Keri Safranski, Dorothy Werderitish, and G.T. Chubb for technical assistance     

Tissue-specific expression of Riken 2810430M08 and its function in T-cell immune responses

Riken 2810430M08 is a gene with unknown functions. According to in situ hybridization (ISH), it presented a pattern of temporal expression, peaking in the mid-gestation (embryonic Days e9-e14) stage in most tissues. In the late-gestation stage and during the adulthood, Riken 2810430M08 was expressed in some tissues with and without a robust proliferation program. Thus, the gene might have important functions that are related and unrelated to proliferation. Its expression was induced after T-cell receptor stimulation in T cells. However, transgenic mice with actin promoter-driven expression of Riken 2810430M08 showed normal in vitro and in vivo T cells responses, such as fetal thymus development, adult T cells activation marker expression, lymphokine secretion, proliferation and migration, and delayed type hypersensitivity (DTH). The expression of Riken 2810430M08 during ontogeny has provided useful clues for further investigation. Additional studies are warranted to examine its role in immune and other systems.     

Analyzing valve interstitial cell mechanics and geometry with spatial statistics

Understanding cell geometric and mechanical properties is crucial to understanding how cells sense and respond to their local environment. Moreover, changes to cell mechanical properties under varied micro-environmental conditions can both influence and indicate fundamental changes to cell behavior. Atomic Force Microscopy (AFM) is a well established, powerful tool to capture geometric and mechanical properties of cells. We have previously demonstrated substantial functional and behavioral differences between aortic and pulmonary valve interstitial cells (VIC) using AFM and subsequent models of VIC mechanical response. In the present work, we extend these studies by demonstrating that to best interpret the spatially distributed AFM data, the use of spatial statistics is required. Spatial statistics includes formal techniques to analyze spatially distributed data, and has been used successfully in the analysis of geographic data. Thus, spatially mapped AFM studies of cell geometry and mechanics are analogous to more traditional forms of geospatial data. We are able to compare the spatial autocorrelation of stiffness in aortic and pulmonary valve interstitial cells, and more accurately capture cell geometry from height recordings. Specifically, we showed that pulmonary valve interstitial cells display higher levels of spatial autocorrelation of stiffness than aortic valve interstitial cells. This suggests that aortic VICs form different stress fiber structures than their pulmonary counterparts, in addition to being more highly expressed and stiffer on average. Thus, the addition of spatial statistics can contribute to our fundamental understanding of the differences between cell types. Moving forward, we anticipate that this work will be meaningful to enhance direct analysis of experimental data and for constructing high fidelity computational of VICs and other cell models.     

Influence of field bed position,ground surface color,mycorrhizal fungi,and high root-zone temperature in woody plant container production

High root-zone temperatures can stress plants and reduce nursery productivity of container produced crops. Field studies were conducted to study position of containers in field beds, ground surface color, mycorrhizal fungi and high root-zone temperatures in the production of selected woody plants. Root-zone temperature profiles in containers were established to determine nursery production conditions for white and black ground bed surfaces. White surfaces increased container medium temperatures in beds of plants with open canopies by 2–4°C compared to full canopied plants. Under field conditions with container medium temperatures as high as 40–50°C, the open canopiedBerberis thunbergii DC. Atropurpurea,Pinus eldarica Medw. andBuxus microphylla Seibold and Zucc. were more susceptible to temeprature stress compared to the more close canopiedPittosporum tobira (Thunb.) Ait. Wheeler's dwarf. When compared to controls,P. tobira colonized with mycorrhizal fungi [Glomus etunicatus Baker and Gerd. andGlomus fasciculatum (Thax.sensu Gerd.) Gerd. and Trappe] had increased shoot growth in all bed areas except the western exposure, and increased root growth in western and eastern bed regions. Greatest root damage generally occurred in containers of colonized and noncolonizedB. thunbergii in southern and western bed exposures. Mycorrhizal colonization did not improve plant growth of the more high temperature susceptibleB. thunbergii.     

Synthesis of lipopeptides of the immunodominant epitope hMBP(83–99) containing amide or C-C bond linked hydrophobic chains for the study of T cell response

We previously demonstrated that the lipopeptide of the myelin basic protein (MBP) immunodominant epitope in Lewis rat Palm-GpMBP(74–85) (Gp: guinea pig), which induced experimental autoimmune encephalomyelitis in vivo strongly increased the T cell proliferative response in vitro. We extended this study to the human immunodominant epitope hMBP(83–99), synthesizing different lipophilic peptides bearing a hydrophobic chain linked through an amide or a C-C bond. To this aim, we developed a synthetic pathway for (±)-N-Fmoc-Ahd-OH (Ahd: 2-aminohexadecanoic acid) which was used to synthesize diastereomeric peptides which were successfully separated by reverse-phase high-performance liquid chromatography. MBP-specific T cell lines recognizing the immunodominant epitope hMBP(83–99) have been generated from patients affected by multiple sclerosis. Their proliferative response to the native peptide and to some lipoderivatives has been investigated. In contrast to the animal model, none of the investigated lipopeptides exhibited superagonist activity.     

The role of protein phosphatase-1 in the modulation of synaptic and structural plasticity

Synaptic plasticity is a phenomenon contributing to changes in the efficacy of neuronal transmission. These changes are widely believed to be a major cellular basis for learning and memory. Protein phosphorylation is a key biochemical process involved in synaptic plasticity that operates through a tight balance between the action of protein kinases and protein phosphatases (PPs). Although the majority of research in this field has concentrated primarily on protein kinases, the significant role of PPs is becoming increasingly apparent. This review examines one such phosphatase, PP1, and highlights recent advances in the understanding of its intervention in synaptic and structural plasticity and the mechanisms of learning and memory.     

Mechanical stretch augments PDGF receptor β expression and protein tyrosine phosphorylation in pulmonary artery tissue and smooth muscle cells

With regard to the mechanotransduction mechanisms of vasculature involved in hypertensive diseases, we aimed to identify tyrosine-phosphorylated proteins in pulmonary artery that responded to mechanical stress. Mechanical stretch simultaneously augmented protein-tyrosine phosphorylation in p55, p95, p105, p115, p130, p165, p180 in pulmonary artery tissue and pulmonary artery-derived smooth muscle cells (PASMC), whereas p115 and p55 were preferentially phosphorylated by the stretch in endothelial cells (PAEC). A series of experiments designed to characterize these proteins indicated that p115 and p180 were focal adhesion kinase (FAK) and platelet-derived growth factor receptor (PDGF-R), respectively, and that stretch augmented the surface-expression of PDGF-R in PASMC but not in PAEC. Moreover, a significant increase in the steady-state mRNA level for PDGF-R was observed in the pulmonary artery of rats with monocrotaline-induced pulmonary hypertension, where the artery should be overstretched due to increasing pulmonary arterial blood pressure. These results suggest that stretch-induced overexpression of cell-surface PDGF-R as well as augmentation of tyrosine phosphorylation of proteins including FAK in PASMC might be involved in the mechanotransduction of pulmonary artery.