image stringlengths 20 66 | question stringclasses 16
values | answer stringlengths 3 10.7k |
|---|---|---|
PMC2014766_F1_14032.jpg | What is the main focus of this visual representation? | Axial CT image through the abdomen demonstrates a well-defined mass arising from the lower pole of the right kidney containing fat and soft tissue elements consistent with an angiomyolipoma. |
PMC2018709_F1_14039.jpg | What can you see in this picture? | A 53-year-old man with reported seizures was evaluated. (A) Head CT without contrast medium reveals a round left occipital mass lesion (arrow) with hyperdense margins and a hypodense center. (B) A T-2-weighted head MRI image without contrast shows a mass (arrow) with high central signal intensity, a ring of heterogeneo... |
PMC2018709_F1_14038.jpg | What object or scene is depicted here? | A 53-year-old man with reported seizures was evaluated. (A) Head CT without contrast medium reveals a round left occipital mass lesion (arrow) with hyperdense margins and a hypodense center. (B) A T-2-weighted head MRI image without contrast shows a mass (arrow) with high central signal intensity, a ring of heterogeneo... |
PMC2018709_F2_14035.jpg | Can you identify the primary element in this image? | The presence of abnormal circulatory shunting was determined by transesophageal bubble-contrast echocardiography. The timing of image acquisition is indicated by the white arrowheads on the ECG strip and explained by the text below the images. (A) Posterior transverse view before agitated saline-air mixture injection (... |
PMC2018709_F2_14036.jpg | What is shown in this image? | The presence of abnormal circulatory shunting was determined by transesophageal bubble-contrast echocardiography. The timing of image acquisition is indicated by the white arrowheads on the ECG strip and explained by the text below the images. (A) Posterior transverse view before agitated saline-air mixture injection (... |
PMC2018709_F2_14037.jpg | What is the core subject represented in this visual? | The presence of abnormal circulatory shunting was determined by transesophageal bubble-contrast echocardiography. The timing of image acquisition is indicated by the white arrowheads on the ECG strip and explained by the text below the images. (A) Posterior transverse view before agitated saline-air mixture injection (... |
PMC2018710_F1_14034.jpg | What is the central feature of this picture? | Ultrasonography, 8.0 MHz. Sagittal section of right testis showing areas of inhomogeneous parenchyma and cystic lesions (arrowhead). |
PMC2018712_F4_14041.jpg | What is shown in this image? | CT scan of the pituitary demonstrating haemorrhage. Patchy enhancement of the pituitary mass is seen indicating haemorrhage within the pituitary macroadenoma. |
PMC2018723_F5_14046.jpg | What key item or scene is captured in this photo? | Subcellular localization of APOBEC proteins. HeLa cells were transfected with 5 μg each of pcDNA-Apo3G (panel A), pcDNA-A3A (panel B), or pcDNA-A3G-3A (panel C). Immediately following transfection, cells were detached from the flasks by trypsinization and re-seeded into 12 well plates containing microscope cover slips.... |
PMC2018723_F5_14044.jpg | What is the core subject represented in this visual? | Subcellular localization of APOBEC proteins. HeLa cells were transfected with 5 μg each of pcDNA-Apo3G (panel A), pcDNA-A3A (panel B), or pcDNA-A3G-3A (panel C). Immediately following transfection, cells were detached from the flasks by trypsinization and re-seeded into 12 well plates containing microscope cover slips.... |
PMC2018723_F5_14045.jpg | What is the core subject represented in this visual? | Subcellular localization of APOBEC proteins. HeLa cells were transfected with 5 μg each of pcDNA-Apo3G (panel A), pcDNA-A3A (panel B), or pcDNA-A3G-3A (panel C). Immediately following transfection, cells were detached from the flasks by trypsinization and re-seeded into 12 well plates containing microscope cover slips.... |
PMC2020442_pone-0001060-g002_14052.jpg | What is shown in this image? | Scotomas identified by the dynamic after effect.Red line represents mean scotoma boundary; grey region indicates 95% confidence interval of estimate. White line represents boundary of dense scotoma identified from microperimetry assessment (except subject TK where scotoma is larger than the area measured using microper... |
PMC2020442_pone-0001060-g002_14049.jpg | What is the dominant medical problem in this image? | Scotomas identified by the dynamic after effect.Red line represents mean scotoma boundary; grey region indicates 95% confidence interval of estimate. White line represents boundary of dense scotoma identified from microperimetry assessment (except subject TK where scotoma is larger than the area measured using microper... |
PMC2020442_pone-0001060-g002_14053.jpg | What is the main focus of this visual representation? | Scotomas identified by the dynamic after effect.Red line represents mean scotoma boundary; grey region indicates 95% confidence interval of estimate. White line represents boundary of dense scotoma identified from microperimetry assessment (except subject TK where scotoma is larger than the area measured using microper... |
PMC2020442_pone-0001060-g002_14051.jpg | What is the central feature of this picture? | Scotomas identified by the dynamic after effect.Red line represents mean scotoma boundary; grey region indicates 95% confidence interval of estimate. White line represents boundary of dense scotoma identified from microperimetry assessment (except subject TK where scotoma is larger than the area measured using microper... |
PMC2020460_F4_14054.jpg | What does this image primarily show? | Transthoracic echocardiogram (TTE 4-chamber). Right sections were dilated with a hypokinetic right ventricle. An image referring to a thrombosis was detected in the rigtht atrium. |
PMC2020464_F1_14060.jpg | What is the dominant medical problem in this image? | Angiographic images showing a bridge on the left anterior descending coronary artery (LAD) in a male patient of 65 years. A1) Right anterior oblique view taken at end systole. The compressed vessel segment is indicated by the two arrows. B1) Left anterior oblique view taken nearly at the same instant. A2) Same view as ... |
PMC2020464_F1_14058.jpg | What is the central feature of this picture? | Angiographic images showing a bridge on the left anterior descending coronary artery (LAD) in a male patient of 65 years. A1) Right anterior oblique view taken at end systole. The compressed vessel segment is indicated by the two arrows. B1) Left anterior oblique view taken nearly at the same instant. A2) Same view as ... |
PMC2020497_pbio-0050277-g003_14070.jpg | What is being portrayed in this visual content? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14064.jpg | What is the focal point of this photograph? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14066.jpg | Can you identify the primary element in this image? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14074.jpg | What is shown in this image? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14062.jpg | What is the main focus of this visual representation? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14068.jpg | Can you identify the primary element in this image? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14072.jpg | What is the core subject represented in this visual? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14063.jpg | What object or scene is depicted here? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14061.jpg | Can you identify the primary element in this image? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020497_pbio-0050277-g003_14067.jpg | What is the principal component of this image? |
hcrtr Is Not Expressed in Monoaminergic Nuclei at 2 dpfResults were all obtained using ISH.(A–D) hcrtr is expressed in the brain and spinal cord. (A) Lateral view of hcrtr expression in telencephalon (t), hypothalamus (ht), hypophysis (hp), posterior tuberculum (pt), and ventral rhombomere 2 (r2). (B) Dorsal view of h... |
PMC2020502_pbio-0050274-g005_14084.jpg | What can you see in this picture? | AMPH-Induced Striatal BOLD fMRI Responses Are Attenuated in STZ-Treated Rats(A) t-thresholded statistical maps (p < ±0.05 to p < ±0.0001; uncorrected comparisons of 15-min baseline period versus 15-min post-injection period) were constructed from subjects that best represent the BOLD signal activation within the DAT- a... |
PMC2020502_pbio-0050274-g005_14081.jpg | What is the focal point of this photograph? | AMPH-Induced Striatal BOLD fMRI Responses Are Attenuated in STZ-Treated Rats(A) t-thresholded statistical maps (p < ±0.05 to p < ±0.0001; uncorrected comparisons of 15-min baseline period versus 15-min post-injection period) were constructed from subjects that best represent the BOLD signal activation within the DAT- a... |
PMC2020502_pbio-0050274-g005_14082.jpg | What does this image primarily show? | AMPH-Induced Striatal BOLD fMRI Responses Are Attenuated in STZ-Treated Rats(A) t-thresholded statistical maps (p < ±0.05 to p < ±0.0001; uncorrected comparisons of 15-min baseline period versus 15-min post-injection period) were constructed from subjects that best represent the BOLD signal activation within the DAT- a... |
PMC2020502_pbio-0050274-g005_14080.jpg | What stands out most in this visual? | AMPH-Induced Striatal BOLD fMRI Responses Are Attenuated in STZ-Treated Rats(A) t-thresholded statistical maps (p < ±0.05 to p < ±0.0001; uncorrected comparisons of 15-min baseline period versus 15-min post-injection period) were constructed from subjects that best represent the BOLD signal activation within the DAT- a... |
PMC2020504_pbio-0050276-g004_14086.jpg | What is the focal point of this photograph? | Detection of Metastasis and Assessment of the Differentiation Status of IC-2 from Mice Infected with RCASBP-Bcl-xL and RCASBP-dnE-cad
(A) Representative images of lymph node metastases found in six mice infected with RCASBP-dnE-cad (upper panel) or in seven mice infected with RCASBP-Bcl-xL (lower panel). Immunohistoche... |
PMC2020504_pbio-0050276-g004_14087.jpg | What object or scene is depicted here? | Detection of Metastasis and Assessment of the Differentiation Status of IC-2 from Mice Infected with RCASBP-Bcl-xL and RCASBP-dnE-cad
(A) Representative images of lymph node metastases found in six mice infected with RCASBP-dnE-cad (upper panel) or in seven mice infected with RCASBP-Bcl-xL (lower panel). Immunohistoche... |
PMC2020504_pbio-0050276-g004_14089.jpg | What stands out most in this visual? | Detection of Metastasis and Assessment of the Differentiation Status of IC-2 from Mice Infected with RCASBP-Bcl-xL and RCASBP-dnE-cad
(A) Representative images of lymph node metastases found in six mice infected with RCASBP-dnE-cad (upper panel) or in seven mice infected with RCASBP-Bcl-xL (lower panel). Immunohistoche... |
PMC2020504_pbio-0050276-g004_14088.jpg | Can you identify the primary element in this image? | Detection of Metastasis and Assessment of the Differentiation Status of IC-2 from Mice Infected with RCASBP-Bcl-xL and RCASBP-dnE-cad
(A) Representative images of lymph node metastases found in six mice infected with RCASBP-dnE-cad (upper panel) or in seven mice infected with RCASBP-Bcl-xL (lower panel). Immunohistoche... |
PMC2031877_F1_14096.jpg | What is shown in this image? | Three virtual sections through 3D models of a 72 hpf embryo (A) and 16 mm fish (B), showing the heart. Multiple virtual sections can be cut from the same 3D reconstructed model. The red lines show the positions of the sections relative to each other. Because of the 3D nature of the data individual structures can be eas... |
PMC2031877_F2_14092.jpg | What is the focal point of this photograph? | Volume rendering of a 15 mm fish. Volume rendering creates a 2D image that gives the impression of a 3D object. By reducing the opacity of the rendering internal structures can be distinguished. |
PMC2031877_F3_14093.jpg | What is shown in this image? | The FishNet interface. Users can determine the plane of section and the position of the section by looking at the volume rendered image top left of the screen. Sections can be selected by dragging the red bar on the volume rendered image, using the cursor keys or by typing in the number of the section they wish to view... |
PMC2031891_F2_14099.jpg | Can you identify the primary element in this image? | Transient expression reveals AtCNGC10-GFP trafficking to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. (A) Leaf protoplasts were transfected with the two constructs pBL-35S:AtCNGC10-EGFP (C10-GFP) and pBL-35S:EGFP alone (GFP), and compared with untransfected controls (WT)... |
PMC2031891_F2_14101.jpg | What can you see in this picture? | Transient expression reveals AtCNGC10-GFP trafficking to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. (A) Leaf protoplasts were transfected with the two constructs pBL-35S:AtCNGC10-EGFP (C10-GFP) and pBL-35S:EGFP alone (GFP), and compared with untransfected controls (WT)... |
PMC2031891_F2_14100.jpg | What object or scene is depicted here? | Transient expression reveals AtCNGC10-GFP trafficking to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. (A) Leaf protoplasts were transfected with the two constructs pBL-35S:AtCNGC10-EGFP (C10-GFP) and pBL-35S:EGFP alone (GFP), and compared with untransfected controls (WT)... |
PMC2031891_F2_14098.jpg | What is the core subject represented in this visual? | Transient expression reveals AtCNGC10-GFP trafficking to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. (A) Leaf protoplasts were transfected with the two constructs pBL-35S:AtCNGC10-EGFP (C10-GFP) and pBL-35S:EGFP alone (GFP), and compared with untransfected controls (WT)... |
PMC2031891_F3_14103.jpg | What is the dominant medical problem in this image? | Immunolocalization of AtCNGC5 and AtCNGC10 to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. Wild type leaf protoplasts were challenged with primary antibodies specific to AtCNGC5 (C5), and AtCNGC10 (C10), followed by AlexaFluor488 anti-rabbit secondary antibodies. A negat... |
PMC2031891_F3_14102.jpg | What is the focal point of this photograph? | Immunolocalization of AtCNGC5 and AtCNGC10 to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. Wild type leaf protoplasts were challenged with primary antibodies specific to AtCNGC5 (C5), and AtCNGC10 (C10), followed by AlexaFluor488 anti-rabbit secondary antibodies. A negat... |
PMC2031891_F3_14108.jpg | What is the principal component of this image? | Immunolocalization of AtCNGC5 and AtCNGC10 to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. Wild type leaf protoplasts were challenged with primary antibodies specific to AtCNGC5 (C5), and AtCNGC10 (C10), followed by AlexaFluor488 anti-rabbit secondary antibodies. A negat... |
PMC2031891_F3_14109.jpg | What does this image primarily show? | Immunolocalization of AtCNGC5 and AtCNGC10 to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. Wild type leaf protoplasts were challenged with primary antibodies specific to AtCNGC5 (C5), and AtCNGC10 (C10), followed by AlexaFluor488 anti-rabbit secondary antibodies. A negat... |
PMC2031891_F3_14104.jpg | What is shown in this image? | Immunolocalization of AtCNGC5 and AtCNGC10 to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. Wild type leaf protoplasts were challenged with primary antibodies specific to AtCNGC5 (C5), and AtCNGC10 (C10), followed by AlexaFluor488 anti-rabbit secondary antibodies. A negat... |
PMC2031891_F3_14107.jpg | What stands out most in this visual? | Immunolocalization of AtCNGC5 and AtCNGC10 to the plasma membrane of Arabidopsis leaf protoplasts using confocal laser scanning microscopy. Wild type leaf protoplasts were challenged with primary antibodies specific to AtCNGC5 (C5), and AtCNGC10 (C10), followed by AlexaFluor488 anti-rabbit secondary antibodies. A negat... |
PMC2031891_F5_14112.jpg | What is the core subject represented in this visual? | Immunolocalization of AtCNGC10 to the plasma membrane of Arabidopsis root cells using TEM. (A) Transverse section of root tip showing three regions (rectangles) examined under TEM labeled with anti-AtCNGC10 antiserum. (B) Root meristematic cell plasma membrane; (C) Root columella cell; m, mitochondria; er, endoplasmic ... |
PMC2031891_F5_14114.jpg | What is the principal component of this image? | Immunolocalization of AtCNGC10 to the plasma membrane of Arabidopsis root cells using TEM. (A) Transverse section of root tip showing three regions (rectangles) examined under TEM labeled with anti-AtCNGC10 antiserum. (B) Root meristematic cell plasma membrane; (C) Root columella cell; m, mitochondria; er, endoplasmic ... |
PMC2031891_F5_14115.jpg | Can you identify the primary element in this image? | Immunolocalization of AtCNGC10 to the plasma membrane of Arabidopsis root cells using TEM. (A) Transverse section of root tip showing three regions (rectangles) examined under TEM labeled with anti-AtCNGC10 antiserum. (B) Root meristematic cell plasma membrane; (C) Root columella cell; m, mitochondria; er, endoplasmic ... |
PMC2031891_F5_14111.jpg | What is shown in this image? | Immunolocalization of AtCNGC10 to the plasma membrane of Arabidopsis root cells using TEM. (A) Transverse section of root tip showing three regions (rectangles) examined under TEM labeled with anti-AtCNGC10 antiserum. (B) Root meristematic cell plasma membrane; (C) Root columella cell; m, mitochondria; er, endoplasmic ... |
PMC2031891_F5_14117.jpg | What is the main focus of this visual representation? | Immunolocalization of AtCNGC10 to the plasma membrane of Arabidopsis root cells using TEM. (A) Transverse section of root tip showing three regions (rectangles) examined under TEM labeled with anti-AtCNGC10 antiserum. (B) Root meristematic cell plasma membrane; (C) Root columella cell; m, mitochondria; er, endoplasmic ... |
PMC2034382_F2_14120.jpg | What does this image primarily show? | vGPCR-expressing HUVEC mimic spindle cells. HUVEC were infected with BABE or BABE-vGPCR retroviruses and grown for 72 hours. GFP-positive vGPCR expressing HUVEC exhibit a spindle cell-like morphology that resemble the spindle cells found in KS lesions. GFP expression ca. 60%. Images taken at 400× magnification. |
PMC2034382_F2_14119.jpg | What is the core subject represented in this visual? | vGPCR-expressing HUVEC mimic spindle cells. HUVEC were infected with BABE or BABE-vGPCR retroviruses and grown for 72 hours. GFP-positive vGPCR expressing HUVEC exhibit a spindle cell-like morphology that resemble the spindle cells found in KS lesions. GFP expression ca. 60%. Images taken at 400× magnification. |
PMC2034382_F2_14121.jpg | What stands out most in this visual? | vGPCR-expressing HUVEC mimic spindle cells. HUVEC were infected with BABE or BABE-vGPCR retroviruses and grown for 72 hours. GFP-positive vGPCR expressing HUVEC exhibit a spindle cell-like morphology that resemble the spindle cells found in KS lesions. GFP expression ca. 60%. Images taken at 400× magnification. |
PMC2034382_F2_14118.jpg | What is being portrayed in this visual content? | vGPCR-expressing HUVEC mimic spindle cells. HUVEC were infected with BABE or BABE-vGPCR retroviruses and grown for 72 hours. GFP-positive vGPCR expressing HUVEC exhibit a spindle cell-like morphology that resemble the spindle cells found in KS lesions. GFP expression ca. 60%. Images taken at 400× magnification. |
PMC2034386_F1_14122.jpg | What's the most prominent thing you notice in this picture? | A photograph of the crystal trophy presented to Dr. Joseph G. Sodroski, winner of the 2006 M. Jeang Retrovirology Prize. |
PMC2034408_fig1_14156.jpg | What is being portrayed in this visual content? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14158.jpg | What is the central feature of this picture? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14145.jpg | What is being portrayed in this visual content? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14151.jpg | Can you identify the primary element in this image? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14160.jpg | What is the main focus of this visual representation? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14161.jpg | What is the dominant medical problem in this image? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14155.jpg | What stands out most in this visual? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14150.jpg | What is the core subject represented in this visual? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14157.jpg | What stands out most in this visual? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14162.jpg | What stands out most in this visual? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14159.jpg | What is being portrayed in this visual content? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14148.jpg | What does this image primarily show? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14146.jpg | What is being portrayed in this visual content? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14154.jpg | Can you identify the primary element in this image? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig1_14149.jpg | What can you see in this picture? | The Cappuccino Pathway Is Not Required for Polarization of the Oocyte Cortex(A and B) GFP-PAR1 linker domain localization in a wild-type stage 9 oocyte (A) and in a capuRK spireRP oocyte (B).(C) α-Tubulin staining of a wild-type stage 9 egg chamber.(D) α-Tubulin staining of a capuRK spireRP egg chamber.(E) Domain struc... |
PMC2034408_fig4_14131.jpg | What object or scene is depicted here? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14129.jpg | What's the most prominent thing you notice in this picture? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14135.jpg | What can you see in this picture? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14137.jpg | What is the principal component of this image? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14141.jpg | What does this image primarily show? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14134.jpg | What stands out most in this visual? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14139.jpg | What stands out most in this visual? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14132.jpg | What is the core subject represented in this visual? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14128.jpg | What stands out most in this visual? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14143.jpg | Can you identify the primary element in this image? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14133.jpg | What is shown in this image? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14130.jpg | Can you identify the primary element in this image? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14125.jpg | Can you identify the primary element in this image? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14126.jpg | What stands out most in this visual? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14124.jpg | What is shown in this image? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14142.jpg | What is the core subject represented in this visual? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig4_14136.jpg | What object or scene is depicted here? | The Effects of Capu and Spire Constructs on Actin Mesh FormationStage 9 (A–F) and stage 11 (G–I) egg chambers stained with TRITC-Phalloidin to label F-actin (gray scale bars, 30 μm; white scale bars, 10 μm). (A′)–(I′) show magnifications of the oocyte cytoplasm, imaged 10 μm (A′–G′) or 20 μm from the cortex (H′–J′), wh... |
PMC2034408_fig5_14177.jpg | What is the dominant medical problem in this image? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14183.jpg | What is the central feature of this picture? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14167.jpg | What's the most prominent thing you notice in this picture? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14184.jpg | What does this image primarily show? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14173.jpg | What can you see in this picture? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14176.jpg | What is the core subject represented in this visual? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14175.jpg | What is the central feature of this picture? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14164.jpg | Can you identify the primary element in this image? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
PMC2034408_fig5_14169.jpg | Can you identify the primary element in this image? | CapuΔN Stabilizes the Actin Mesh against Latrunculin-A-Induced DepolymerizationConfocal images of stage 9 egg chambers after treatment with Latrunculin A. (A), (D), (G), (J), and (M) show the cytoplasmic movements in living egg chambers; (B), (E), (H), (K), and (N) are egg chambers stained with TRITC-Phalloidin to labe... |
Subsets and Splits
No community queries yet
The top public SQL queries from the community will appear here once available.