Subcellular localization and in vivo identification of the putative movement protein of olive latent virus 2.

Anthocyanins belong to the group of flavonoid compounds broadly distributed in plant species responsible for attractive colors. In black rice (Oryza sativa L.), they are present in the stems, leaves, stigmas, and caryopsis. However, there is still no scientific evidence supporting the existence of compartmentalization and trafficking of anthocyanin inside the cells. In the current study, we took advantage of autofluorescence with anthocyanin’s unique excitation/emission properties to elucidate the subcellular localization of anthocyanin and report on the in planta characterization of anthocyanin prevacuolar vesicles (APV) and anthocyanic vacuolar inclusion (AVI) structure. Protoplasts were isolated from the stigma of black and brown rice and imaging using a confocal microscope. Our result showed the fluorescence displaying magenta color in purple stigma and no fluorescence in white stigma when excitation was provided by a helium–neon 552 nm and emission long pass 610–670 nm laser. The fluorescence was distributed throughout the cell, mainly in the central vacuole. Fluorescent images revealed two pools of anthocyanin inside the cells. The diffuse pools were largely found inside the vacuole lumen, while the body structures could be observed mostly inside the cytoplasm (APV) and slightly inside the vacuole (AVI) with different shapes, sizes, and color intensity. Based on their sizes, AVI could be grouped into small (Ф < 0.5 um), middle (Ф between 0.5 and 1 um), and large size (Ф > 1 um). Together, these results provided evidence about the sequestration and trafficking of anthocyanin from the cytoplasm to the central vacuole and the existence of different transport mechanisms of anthocyanin. Our results suggest that stigma cells are an excellent system for in vivo studying of anthocyanin in rice and provide a good foundation for understanding anthocyanin metabolism in plants, sequestration, and trafficking in black rice.

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Impact of Membrane Lipids on UapA and AzgA Transporter Subcellular Localization and Activity in Aspergillus nidulans

Journal of Fungi ◽

10.3390/jof7070514 ◽

2021 ◽

Vol 7 (7) ◽

pp. 514

Author(s):

Mariangela Dionysopoulou ◽

George Diallinas

Keyword(s):

Plasma Membrane ◽

Subcellular Localization ◽

Aspergillus Nidulans ◽

Membrane Lipids ◽

Membrane Lipid ◽

Lipid Biosynthesis ◽

Transport Kinetics ◽

Negative Effect ◽

And Function

Recent biochemical and biophysical evidence have established that membrane lipids, namely phospholipids, sphingolipids and sterols, are critical for the function of eukaryotic plasma membrane transporters. Here, we study the effect of selected membrane lipid biosynthesis mutations and of the ergosterol-related antifungal itraconazole on the subcellular localization, stability and transport kinetics of two well-studied purine transporters, UapA and AzgA, in Aspergillus nidulans. We show that genetic reduction in biosynthesis of ergosterol, sphingolipids or phosphoinositides arrest A. nidulans growth after germling formation, but solely blocks in early steps of ergosterol (Erg11) or sphingolipid (BasA) synthesis have a negative effect on plasma membrane (PM) localization and stability of transporters before growth arrest. Surprisingly, the fraction of UapA or AzgA that reaches the PM in lipid biosynthesis mutants is shown to conserve normal apparent transport kinetics. We further show that turnover of UapA, which is the transporter mostly sensitive to membrane lipid content modification, occurs during its trafficking and by enhanced endocytosis, and is partly dependent on autophagy and Hect-type HulARsp5 ubiquitination. Our results point out that the role of specific membrane lipids on transporter biogenesis and function in vivo is complex, combinatorial and transporter-dependent.

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Differential effect of subcellular localization of communication impairing gap junction protein connexin43 on tumor cell growth in vivo

Oncogene ◽

10.1038/sj.onc.1203340 ◽

2000 ◽

Vol 19 (4) ◽

pp. 505-513 ◽

Cited By ~ 55

Author(s):

V A Krutovskikh ◽

S M Troyanovsky ◽

C Piccoli ◽

H Tsuda ◽

M Asamoto ◽

...

Keyword(s):

Cell Growth ◽

Subcellular Localization ◽

Tumor Cell ◽

Gap Junction ◽

Differential Effect ◽

Tumor Cell Growth ◽

Junction Protein ◽

Gap Junction Protein

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Tobacco Mosaic Virus Movement Protein Functions as a Structural Microtubule-Associated Protein

Journal of Virology ◽

10.1128/jvi.00540-06 ◽

2006 ◽

Vol 80 (17) ◽

pp. 8329-8344 ◽

Cited By ~ 67

Author(s):

Jamie Ashby ◽

Emmanuel Boutant ◽

Mark Seemanpillai ◽

Adrian Sambade ◽

Christophe Ritzenthaler ◽

...

Keyword(s):

Tobacco Mosaic Virus ◽

Mosaic Virus ◽

Movement Protein ◽

Cell Extract ◽

Transport Processes ◽

In Vitro Assays ◽

Protein Functions ◽

Intercellular Spread

ABSTRACT The cell-to-cell spread of Tobacco mosaic virus infection depends on virus-encoded movement protein (MP), which is believed to form a ribonucleoprotein complex with viral RNA (vRNA) and to participate in the intercellular spread of infectious particles through plasmodesmata. Previous studies in our laboratory have provided evidence that the vRNA movement process is correlated with the ability of the MP to interact with microtubules, although the exact role of this interaction during infection is not known. Here, we have used a variety of in vivo and in vitro assays to determine that the MP functions as a genuine microtubule-associated protein that binds microtubules directly and modulates microtubule stability. We demonstrate that, unlike MP in whole-cell extract, microtubule-associated MP is not ubiquitinated, which strongly argues against the hypothesis that microtubules target the MP for degradation. In addition, we found that MP interferes with kinesin motor activity in vitro, suggesting that microtubule-associated MP may interfere with kinesin-driven transport processes during infection.

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Ethanol metabolism in guinea pig: In vivo ethanol elimination, alcohol dehydrogenase distribution, and subcellular localization of acetaldehyde dehydrogenase in liver

Archives of Biochemistry and Biophysics ◽

10.1016/0003-9861(81)90044-8 ◽

1981 ◽

Vol 207 (2) ◽

pp. 371-379 ◽

Cited By ~ 18

Author(s):

Rainer N. Zahlten ◽

Michael E. Nejtek ◽

Jan C. Jacobson

Keyword(s):

Alcohol Dehydrogenase ◽

Guinea Pig ◽

Subcellular Localization ◽

Ethanol Metabolism ◽

Acetaldehyde Dehydrogenase ◽

Ethanol Elimination

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Localization of the rat myosin I molecules myr 1 and myr 2 and in vivo targeting of their tail domains

Journal of Cell Science ◽

10.1242/jcs.108.12.3775 ◽

1995 ◽

Vol 108 (12) ◽

pp. 3775-3786 ◽

Cited By ~ 9

Author(s):

C. Ruppert ◽

J. Godel ◽

R.T. Muller ◽

R. Kroschewski ◽

J. Reinhard ◽

...

Keyword(s):

Subcellular Localization ◽

Brush Border ◽

Subcellular Fractionation ◽

Actin Binding ◽

Resting Cells ◽

Medium Density ◽

Subcellular Targeting ◽

Myosin I ◽

Punctate Pattern

Myr 1 is a widely distributed mammalian myosin I molecule related to brush border myosin 1. A second widely distributed myosin I molecule similar to myr 1 and brush border myosin I, called myr 2, has now been identified. Specific antibodies and expression of epitope-tagged molecules were used to determine the subcellular localization of myr 1 and myr 2 in NRK cells. Myr 1 was detected at the plasma membrane and was particularly enriched in cell protrusions like lamellipodia, membrane ruffles and filopodia. In dividing cells myr 1 localized to the cleavage furrow. Myr 2 was localized in a discrete punctate pattern in resting cells and in cells undergoing cytokinesis. In subcellular fractionation experiments myr 1 and myr 2 were both partly soluble and partly associated with smooth membranes of medium density. The tail domains of myosin I molecules have been proposed to interact with a receptor and thereby determine the subcellular localization. To test this hypothesis we expressed the tail domains of myr 1 and myr 2 that lack the F-actin-binding myosin head domain in NRK cells. These tail domains also partly copurified with smooth membranes of medium density and immunolocalized similar to the respective endogenous myosin I; however, they exhibited a lower affinity for membranes and an increased diffuse cytosolic localization. These results suggest that the tail domains of myr 1 and myr 2 are sufficient for subcellular targeting but that their head domains also contribute significantly to maintaining a proper subcellular localization.

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