35 research outputs found

    Bakteri Tanah Sampah Pendegradasi Plastik dalam Kolom Winogradsky

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    Penggunaan plastik berupa kantong kresek hasil daur ulang dengan berbagai warna sangat diminati oleh masyarakat. Sifat plastik yang tidak mudah terdegradasi di alam mengakibatkan masalah lingkungan. Penelitian ini dilakukan untuk mengisolasi dan mengkarakterisasi bakteri tanah sampah yang mampu mendegradasi plastik secara biokimia. Parameter biodegradasi plastik yang diukur adalah prosentase kehilangan berat kering, pengukuran densitas sel biofilm, densitas sel kolom air dan pH tiap bulan selama 4 bulan masa inkubasi. Dari penelitian didapatkan persentase kehilangan berat kerig plastk hitam lebih tinggi daripada plastik putih Bening. Hasil yang diperoleh menunjukkan bahwa isolat bakteri tanah sampah pendegradasi plastik yaitu Gram positif basil (PPs 2, PPs 7, PPs 9, dan PPs 11) dan Gram negatif basil (PPs 1, PPs 4, PPs 5, PPs 6, PPs 8, PPs 10, PPs 12 dan PPs 13 )dan hanya PPs 3 termasuk Gram negatif kokus

    Diabetic nephropathy: nitric oxide and renal medullary hypoxia

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    Classical estrogen receptors and ERĪ± splice variants in the mouse.

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    Estrogens exert a variety of effects in both reproductive and non-reproductive tissues. With the discovery of ERĪ± splice variants, prior assumptions concerning tissue-specific estrogen signaling need to be re-evaluated. Accordingly, we sought to determine the expression of the classical estrogen receptors and ERĪ± splice variants across reproductive and non-reproductive tissues of male and female mice. Western blotting revealed that the full-length ERĪ±66 was mainly present in female reproductive tissues but was also found in non-reproductive tissues at lower levels. ERĪ±46 was most highly expressed in the heart of both sexes. ERĪ±36 was highly expressed in the kidneys and liver of female mice but not in the kidneys of males. ERĪ² was most abundant in non-reproductive tissues and in the ovaries. Because the kidney has been reported to be the most estrogenic non-reproductive organ, we sought to elucidate ER renal expression and localization. Immunofluorescence studies revealed ERĪ±66 in the vasculature and the glomerulus. It was also found in the brush border of the proximal tubule and in the cortical collecting duct of female mice. ERĪ±36 was evident in mesangial cells and tubular epithelial cells of both sexes, as well as podocytes of females but not males. ERĪ² was found primarily in the podocytes in female mice but was also present in the mesangial cells in both sexes. Within the renal cortex, ERĪ±46 and ERĪ±36 were mainly located in the membrane fraction although they were also present in the cytosolic fraction. Given the variability of expression patterns demonstrated herein, identification of the specific estrogen receptors expressed in a tissue is necessary for interpreting estrogenic effects. As this study revealed expression of the ERĪ± splice variants at multiple sites within the kidney, further studies are warranted in order to elucidate the contribution of these receptors to renal estrogen responsiveness

    Renal AT

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    Experiments were performed to evaluate the hypothesis that the early stage of Type 1 diabetes mellitus (DM) increases renal angiotensin II (AngII) concentration and angiotensin type 1 (AT(1)) receptor protein levels. Nineteen or twenty days after vehicle (Sham rats) or streptozotocin (STZ rats) treatment, plasma [AngII] was higher in STZ rats (152Ā±23 fmol/ml) than in Sham rats (101Ā±7 fmol/ml); however, kidney [AngII] did not differ between groups. AT(1) receptor protein expression was greater in STZ kidneys than in Sham kidneys. This increase was restricted to the cortex, where AT(1) protein levels were elevated by 77Ā±26% (42 kDa) and 101Ā±16% (58 kDa) in STZ kidneys. Immunohistochemistry revealed this effect to be most evident in distal nephron segments including the connecting tubule/cortical collecting duct. Increased renal cortical AT(1) receptor protein and circulating AngII levels are consistent with an exaggerated AngII-dependent influence on renal function during the early stage of DM in the rat

    Representative immunofluorescence images localizing ERĪ² in mouse kidney.

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    <p>Green fluorescence represents ERĪ² in all images. Red fluorescence represents cell specific markers for co-localization (collecting duct marker, aquaporin 2; vascular smooth muscle & mesangial cell marker, Ī±-smooth muscle actin; podocyte cell marker, synaptopodin). Nuclei are stained blue with DAPI. Scale barā€Š=ā€Š20 Āµm.</p

    ERĪ² protein level in various organs of mice.

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    <p>Shown are representative Western blots and quantification for expression in non-reproductive and reproductive organs harvested from female and male mice. Data are shown as percent of ERĪ² in female kidney. *<i>P</i><0.05 vs. female kidney, <sup>Ā§</sup><i>P</i><0.05 vs. male liver, <b><sup>ā€ </sup></b><i>P</i><0.05 vs. female liver, <sup>Ā¶</sup><i>P</i><0.05 vs. heart (of same sex), <sup>Ā„</sup><i>P</i><0.05 vs. ovary (<i>n</i>ā€Š=ā€Š4 per group).</p

    ERĪ±46 and ERĪ±36 protein level in membrane and cytosolic fractions from the renal cortices of female mice.

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    <p>Shown are representative Western blots and quantification for ERĪ± splice variant expression in membrane and cytosolic fractions from the renal cortices from female mice. *<i>P</i><0.05 vs. membrane fraction.</p

    ERĪ±66 protein level in various organs of mice.

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    <p>Shown are representative Western blots and quantification for expression in non-reproductive and reproductive organs harvested from female and male mice. Data are shown as percent of ERĪ±66 in female kidney, plotted on a logarithmic scale. *<i>P</i><0.05 vs. female kidney, <b><sup>ā€ </sup></b><i>P</i><0.05 vs. female liver, <sup>Ā¶</sup><i>P</i><0.05 vs. female heart (<i>n</i>ā€Š=ā€Š4ā€“5 per group).</p
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