d-eclipse confocal 90i microscope Search Results


d eclipse ci confocal microscope  (Nikon)
99
Nikon d eclipse ci confocal microscope
D Eclipse Ci Confocal Microscope, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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d eclipse c1 confocal microscope  (Nikon)
99
Nikon d eclipse c1 confocal microscope
D Eclipse C1 Confocal Microscope, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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bx50 fluoview  (Evident Corporation)
90
Evident Corporation bx50 fluoview
Bx50 Fluoview, supplied by Evident Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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griot 488 ion laser  (Melles Griot)
90
Melles Griot griot 488 ion laser
RGMb can be expressed on the cell surface but is primarily localized intracellularly. (a) RGMb cell surface expression on human breast cancer cell lines (MDA-231, SKBR-3, and MCF-7), the nonsmall cell lung cancer cell line NCI-H226, and the renal cancer cell line SN12C was analyzed by flow cytometry with mAb 1H6 (red) or isotype control (blue). (b) RGMb expression by Western blotting using mAb 1H6. The loading amount was 60–80 µg/lane except for 0.5 µg/lane for 300-hRGMb. (c) SKBR-3 cells were stained for RGMb (1H6-biotin) or isotype control plus streptavidin-Alexa Fluor <t>488</t> (green), and then with Phalloidin-TRIC to label F-actin, and analyzed <t>by</t> <t>confocal</t> microscopy. Bars, 25 µm. (d) RGMb expression by Western blotting using mAb 1H6. The loading amount was 60–80 µg/lane, except for 0.5 µg/lane for 300-mRGMb cells. (e) Splenocytes from naive mice and mice treated with FLT-3L as well as 300-mPD-L2 cells (negative control) were stained for surface markers CD3, CD19, and CD11c. Then intracellular flow cytometry staining with PE-conjugated RGMb mAb 9D1 (red) or rat IgG2a (blue) was used to analyze RGMb expression in these cells. (f) RGMb expression in unstimulated cells from the indicated mouse organs by qRT-PCR. Data are mean ± SEM; n = 2; *, P < 0.05; **, P < 0.01. Ordinary one-way ANOVA followed by Dunnett’s multiple comparison test. (g) RGMb expression in lung AM and IM by Western blotting as in d. All data are representative of two or more experiments.
Griot 488 Ion Laser, supplied by Melles Griot, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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confocal laser scanning microscope zeiss lsm780  (Carl Zeiss)
90
Carl Zeiss confocal laser scanning microscope zeiss lsm780
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Confocal Laser Scanning Microscope Zeiss Lsm780, supplied by Carl Zeiss, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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confocal microscope zeiss 510-meta  (Carl Zeiss)
90
Carl Zeiss confocal microscope zeiss 510-meta
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Confocal Microscope Zeiss 510 Meta, supplied by Carl Zeiss, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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confocal laser scanning microscope zeiss lsm 710  (Carl Zeiss)
90
Carl Zeiss confocal laser scanning microscope zeiss lsm 710
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Confocal Laser Scanning Microscope Zeiss Lsm 710, supplied by Carl Zeiss, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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d eclipse ci confocal module  (Nikon)
95
Nikon d eclipse ci confocal module
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
D Eclipse Ci Confocal Module, supplied by Nikon, used in various techniques. Bioz Stars score: 95/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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inverted zeiss observer.z1 equipped with a lsm780 confocal unit and 940 water immersion objective  (Carl Zeiss)
90
Carl Zeiss inverted zeiss observer.z1 equipped with a lsm780 confocal unit and 940 water immersion objective
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Inverted Zeiss Observer.Z1 Equipped With A Lsm780 Confocal Unit And 940 Water Immersion Objective, supplied by Carl Zeiss, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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inverted microscope  (Nikon)
99
Nikon inverted microscope
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Inverted Microscope, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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upright nikon d eclipse microscope  (Nikon)
99
Nikon upright nikon d eclipse microscope
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Upright Nikon D Eclipse Microscope, supplied by Nikon, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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lsm exciter confocal microscope  (Carl Zeiss)
90
Carl Zeiss lsm exciter confocal microscope
Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single <t>CLSM</t> sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm
Lsm Exciter Confocal Microscope, supplied by Carl Zeiss, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Image Search Results


RGMb can be expressed on the cell surface but is primarily localized intracellularly. (a) RGMb cell surface expression on human breast cancer cell lines (MDA-231, SKBR-3, and MCF-7), the nonsmall cell lung cancer cell line NCI-H226, and the renal cancer cell line SN12C was analyzed by flow cytometry with mAb 1H6 (red) or isotype control (blue). (b) RGMb expression by Western blotting using mAb 1H6. The loading amount was 60–80 µg/lane except for 0.5 µg/lane for 300-hRGMb. (c) SKBR-3 cells were stained for RGMb (1H6-biotin) or isotype control plus streptavidin-Alexa Fluor 488 (green), and then with Phalloidin-TRIC to label F-actin, and analyzed by confocal microscopy. Bars, 25 µm. (d) RGMb expression by Western blotting using mAb 1H6. The loading amount was 60–80 µg/lane, except for 0.5 µg/lane for 300-mRGMb cells. (e) Splenocytes from naive mice and mice treated with FLT-3L as well as 300-mPD-L2 cells (negative control) were stained for surface markers CD3, CD19, and CD11c. Then intracellular flow cytometry staining with PE-conjugated RGMb mAb 9D1 (red) or rat IgG2a (blue) was used to analyze RGMb expression in these cells. (f) RGMb expression in unstimulated cells from the indicated mouse organs by qRT-PCR. Data are mean ± SEM; n = 2; *, P < 0.05; **, P < 0.01. Ordinary one-way ANOVA followed by Dunnett’s multiple comparison test. (g) RGMb expression in lung AM and IM by Western blotting as in d. All data are representative of two or more experiments.

Journal: The Journal of Experimental Medicine

Article Title: RGMb is a novel binding partner for PD-L2 and its engagement with PD-L2 promotes respiratory tolerance

doi: 10.1084/jem.20130790

Figure Lengend Snippet: RGMb can be expressed on the cell surface but is primarily localized intracellularly. (a) RGMb cell surface expression on human breast cancer cell lines (MDA-231, SKBR-3, and MCF-7), the nonsmall cell lung cancer cell line NCI-H226, and the renal cancer cell line SN12C was analyzed by flow cytometry with mAb 1H6 (red) or isotype control (blue). (b) RGMb expression by Western blotting using mAb 1H6. The loading amount was 60–80 µg/lane except for 0.5 µg/lane for 300-hRGMb. (c) SKBR-3 cells were stained for RGMb (1H6-biotin) or isotype control plus streptavidin-Alexa Fluor 488 (green), and then with Phalloidin-TRIC to label F-actin, and analyzed by confocal microscopy. Bars, 25 µm. (d) RGMb expression by Western blotting using mAb 1H6. The loading amount was 60–80 µg/lane, except for 0.5 µg/lane for 300-mRGMb cells. (e) Splenocytes from naive mice and mice treated with FLT-3L as well as 300-mPD-L2 cells (negative control) were stained for surface markers CD3, CD19, and CD11c. Then intracellular flow cytometry staining with PE-conjugated RGMb mAb 9D1 (red) or rat IgG2a (blue) was used to analyze RGMb expression in these cells. (f) RGMb expression in unstimulated cells from the indicated mouse organs by qRT-PCR. Data are mean ± SEM; n = 2; *, P < 0.05; **, P < 0.01. Ordinary one-way ANOVA followed by Dunnett’s multiple comparison test. (g) RGMb expression in lung AM and IM by Western blotting as in d. All data are representative of two or more experiments.

Article Snippet: Images were taken using a Nikon d -Eclipse C1 confocal microscope equipped with a Melles Griot 488 Ion Laser (with a 515/30 emission filter), a Melles Griot 543 Laser (with a 590/50 emission filter), a Melles Griot 640 Laser, and the Confocal Acquisition Software Nikon EZ-C1 version 3.90.

Techniques: Expressing, Flow Cytometry, Control, Western Blot, Staining, Confocal Microscopy, Negative Control, Quantitative RT-PCR, Comparison

Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single CLSM sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm

Journal: Journal of Biological Research

Article Title: Cortical microtubule orientation in Arabidopsis thaliana root meristematic zone depends on cell division and requires severing by katanin

doi: 10.1186/s40709-018-0082-6

Figure Lengend Snippet: Cortical microtubule orientation in the meristematic zone of untreated ( a ) and aphidicolin-treated ( b – d ) roots. Single CLSM sections through the boundary between protoderm and cortex are presented, so that in the center of each figure cortex cells can be observed. In all the images of this work the root tip is oriented towards the bottom of the page. In control root ( a ) prominent transverse orientation of cortical microtubules can be observed in interphase cells (arrowheads). At 12 h of treatment ( b ) transverse microtubule orientation persists (arrowheads), while dividing cells still exist (arrow points to a mitotic cell). After 24 h of treatment ( c ), cell divisions have ceased and cortical microtubules exhibit random orientation (cells within the brackets are cortex cells viewed at external cortical plane), which is also observed after 48 h of treatment ( d ; cells within brackets). In the latter image, vacuolation of meristematic cells in also prominent (asterisks show vacuoles). Representative decipher-graphs of microtubule alignment in meristematic cells of control ( e ), 12 h ( f ), 24 h ( g ) and 48 h ( h ) aphidicolin treatments. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 12 h of aphidicolin treatment ( e , f ), while the frequency of longitudinal and randomly oriented microtubules increased upon prolonged treatments ( g , h , respectively). Scale bar 10 μm

Article Snippet: The preparations were examined with a Nikon D-Eclipse C1 or a Zeiss LSM780 confocal laser scanning microscope (CLSM), with the appropriate filters for FITC, and micrographs were acquired with each manufacturer’s software.

Techniques: Control

Cortical microtubule orientation at the external face of epidermal cells in the transition (i.e. under the shootward part of the lateral root cap; a , c ) and fast elongation ( b , d ) zones of aphidicolin-treated roots. All images are maximum projections of serial CLSM sections. After 24 h of treatment, microtubules are transverse (arrowheads) in the transition ( a ) and fast elongation ( b ) zone, while after 48 h of treatment they appear randomly oriented in both zones ( c , d ). Representative decipher-graphs of microtubule alignment in transition and elongation zone cells of control roots ( e ), and after 24 h ( f ) and 48 h ( g ) of aphidicolin treatment. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 24 h of aphidicolin treatment ( e and f , respectively), while the frequency of longitudinal and/or randomly oriented microtubules increased after 48 h of treatment ( g ). Scale bar 10 μm

Journal: Journal of Biological Research

Article Title: Cortical microtubule orientation in Arabidopsis thaliana root meristematic zone depends on cell division and requires severing by katanin

doi: 10.1186/s40709-018-0082-6

Figure Lengend Snippet: Cortical microtubule orientation at the external face of epidermal cells in the transition (i.e. under the shootward part of the lateral root cap; a , c ) and fast elongation ( b , d ) zones of aphidicolin-treated roots. All images are maximum projections of serial CLSM sections. After 24 h of treatment, microtubules are transverse (arrowheads) in the transition ( a ) and fast elongation ( b ) zone, while after 48 h of treatment they appear randomly oriented in both zones ( c , d ). Representative decipher-graphs of microtubule alignment in transition and elongation zone cells of control roots ( e ), and after 24 h ( f ) and 48 h ( g ) of aphidicolin treatment. Decipher-graphs show that microtubules are transversely oriented (doubled-headed arrow) in the control and after 24 h of aphidicolin treatment ( e and f , respectively), while the frequency of longitudinal and/or randomly oriented microtubules increased after 48 h of treatment ( g ). Scale bar 10 μm

Article Snippet: The preparations were examined with a Nikon D-Eclipse C1 or a Zeiss LSM780 confocal laser scanning microscope (CLSM), with the appropriate filters for FITC, and micrographs were acquired with each manufacturer’s software.

Techniques: Control

Cortical microtubule orientation in cortex cells of wild-type ( a , e ) and p60-katanin mutants ( b – d , f – h ). All high magnification images ( e – h ) are maximum projections of serial CLSM sections through the cortical cytoplasm. Cortex cell files, derived from the areas defined by rectangular frames on low magnification images ( a – d ), were released after application of gentle pressure on the whole mount root specimens. Fairly transverse cortical microtubules can be observed in Col-0 cells ( e ). In ktn1 - 2 ( f ), lue1 ( g ) and fra2 ( h ), though a general transverse pattern exists, several microtubules exhibit random orientation, while foci of microtubule convergence can be discerned as well. Representative decipher-graphs of microtubule alignment in meristematic cortex cells of Col-0 ( i ), ktn1 - 2 ( j ), lue1 ( k ) and fra2 ( l ). Generally, transverse microtubule orientation prevailed in all the cases (doubled-headed arrow). However, in the katanin mutants an increase in the frequency of longitudinal and/or randomly oriented microtubules was noticed. Scale bars 50 μm ( a – d ), 10 μm ( e – h )

Journal: Journal of Biological Research

Article Title: Cortical microtubule orientation in Arabidopsis thaliana root meristematic zone depends on cell division and requires severing by katanin

doi: 10.1186/s40709-018-0082-6

Figure Lengend Snippet: Cortical microtubule orientation in cortex cells of wild-type ( a , e ) and p60-katanin mutants ( b – d , f – h ). All high magnification images ( e – h ) are maximum projections of serial CLSM sections through the cortical cytoplasm. Cortex cell files, derived from the areas defined by rectangular frames on low magnification images ( a – d ), were released after application of gentle pressure on the whole mount root specimens. Fairly transverse cortical microtubules can be observed in Col-0 cells ( e ). In ktn1 - 2 ( f ), lue1 ( g ) and fra2 ( h ), though a general transverse pattern exists, several microtubules exhibit random orientation, while foci of microtubule convergence can be discerned as well. Representative decipher-graphs of microtubule alignment in meristematic cortex cells of Col-0 ( i ), ktn1 - 2 ( j ), lue1 ( k ) and fra2 ( l ). Generally, transverse microtubule orientation prevailed in all the cases (doubled-headed arrow). However, in the katanin mutants an increase in the frequency of longitudinal and/or randomly oriented microtubules was noticed. Scale bars 50 μm ( a – d ), 10 μm ( e – h )

Article Snippet: The preparations were examined with a Nikon D-Eclipse C1 or a Zeiss LSM780 confocal laser scanning microscope (CLSM), with the appropriate filters for FITC, and micrographs were acquired with each manufacturer’s software.

Techniques: Derivative Assay, Gentle