scholarly journals P38α‐MAPK phosphorylates Snapin and reduces Snapin‐mediated BACE1 transportation in APP‐transgenic mice

2021 ◽  
Vol 35 (7) ◽  
Author(s):  
Laura Schnöder ◽  
Inge Tomic ◽  
Laura Schwindt ◽  
Dominic Helm ◽  
Mandy Rettel ◽  
...  
Keyword(s):  
2021 ◽  
Author(s):  
Qinghua Luo ◽  
Laura Schnöder ◽  
Wenlin Hao ◽  
Kathrin Litzenburger ◽  
Yann Decker ◽  
...  

Microglial activation is a hall marker of Alzheimer disease (AD); its pathogenic role and regulating mechanisms are unclear. In APP-transgenic mice, we deleted p38α-MAPK in the myeloid cell lineage from birth or specifically in microglia from 9 months, and analysed the AD pathology at the age of 4, 9 and 12 months. In both experimental settings, p38α-MAPK deficiency decreased cerebral Aβ and improved cognitive function in AD mice; however, p38α-MAPK deficiency in whole myeloid cells was more effective than specifically in microglia in preventing AD pathogenesis. Deficiency of p38α-MAPK in whole myeloid cells inhibited the inflammatory activation of individual microglia by 4 months, but enhanced it by 9 months. Inflammatory activation was essential for p38α-MAPK deficiency to promote microglial internalization of Aβ in the brain. In the investigation of mechanisms mediating different effects of p38α-MAPK-deficient myeloid cells and p38α-MAPK-deficient microglia on the pathogenesis of AD mice, we observed that p38α-MAPK deficiency in peripheral myeloid cells reduced il-17a transcription in CD4-positive spleen cells. By cross-breeding APP-transgenic mice and IL-17a knockout mice, we further found that IL-17a deficiency activated microglia and decreased Aβ deposits in AD mouse brain. In summary, our study shows that p38α-MAPK deficiency in myeloid cells attenuates symptoms and pathology of APP-transgenic mice. As a potential mechanism, p38α-MAPK-deficient peripheral myeloid cells reduces IL-17a-expressing T lymphocytes, and subsequently regulates cerebral Aβ clearance in APP-transgenic mice. Together with our previous observations that a deficiency of p38α-MAPK in neurons prevents AD pathogenesis, our study supports p38α-MAPK as a novel target for AD therapy.


Author(s):  
C. G. Plopper ◽  
C. Helton ◽  
A. J. Weir ◽  
J. A. Whitsett ◽  
T. R. Korfhagen

A wide variety of growth factors are thought to be involved in the regulation of pre- and postnatal lung maturation, including factors which bind to the epidermal growth factor receptor. Marked pulmonary fibrosis and enlarged alveolar air spaces have been observed in lungs of transgenic mice expressing human TGF-α under control of the 3.7 KB human SP-C promoter. To test whether TGF-α alters lung morphogenesis and cellular differentiation, we examined morphometrically the lungs of adult (6-10 months) mice derived from line 28, which expresses the highest level of human TGF-α transcripts among transgenic lines. Total volume of lungs (LV) fixed by airway infusion at standard pressure was similar in transgenics and aged-matched non-transgenic mice (Fig. 1). Intrapulmonary bronchi and bronchioles made up a smaller percentage of LV in transgenics than in non-transgenics (Fig. 2). Pulmonary arteries and pulmonary veins were a smaller percentage of LV in transgenic mice than in non-transgenics (Fig. 3). Lung parenchyma (lung tissue free of large vessels and conducting airways) occupied a larger percentage of LV in transgenics than in non-transgenics (Fig. 4). The number of generations of branching in conducting airways was significantly reduced in transgenics as compared to non-transgenic mice. Alveolar air space size, as measured by mean linear intercept, was almost twice as large in transgenic mice as in non-transgenics, especially when different zones within the lung were compared (Fig. 5). Alveolar air space occupied a larger percentage of the lung parenchyma in transgenic mice than in non-transgenic mice (Fig. 6). Collagen abundance was estimated in histological sections as picro-Sirius red positive material by previously-published methods. In intrapulmonary conducting airways, collagen was 4.8% of the wall in transgenics and 4.5% of the wall in non-transgenic mice. Since airways represented a smaller percentage of the lung in transgenics, the volume of interstitial collagen associated with airway wall was significantly less. In intrapulmonary blood vessels, collagen was 8.9% of the wall in transgenics and 0.7% of the wall in non-transgenics. Since blood vessels were a smaller percentage of the lungs in transgenics, the volume of collagen associated with the walls of blood vessels was five times greater. In the lung parenchyma, collagen was 51.5% of the tissue volume in transgenics and 21.2% in non-transgenics. Since parenchyma was a larger percentage of lung volume in transgenics, but the parenchymal tissue was a smaller percent of the volume, the volume of collagen associated with parenchymal tissue was only slightly greater. We conclude that overexpression of TGF-α during lung maturation alters many aspects of lung development, including branching morphogenesis of the airways and vessels and alveolarization in the parenchyma. Further, the increases in visible collagen previously associated with pulmonary fibrosis due to the overexpression of TGF-α are a result of actual increases in amounts of collagen and in a redistribution of collagen within compartments which results from morphogenetic changes. These morphogenetic changes vary by lung compartment. Supported by HL20748, ES06700 and the Cystic Fibrosis Foundation.


1992 ◽  
Vol 25 (5) ◽  
pp. 1017-1026 ◽  
Author(s):  
Rick A. Friedman ◽  
Allen F. Ryan
Keyword(s):  

2003 ◽  
Vol 2 (1) ◽  
pp. 15-16
Author(s):  
A KOSTAREVA ◽  
G SJOBERG ◽  
K AMINEVA ◽  
A GUDKOVA ◽  
T SEJERSEN ◽  
...  

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