Drosophila micrograph hi-res stock photography and images

Head of Drosophila melanogaster, reflected light micrograph Stock Photo

RMT5A5PM–Head of Drosophila melanogaster, reflected light micrograph

Vinegar fly or fruit fly (Drosophila melanogaster) head detail. Light microscope X150 at 10 cm wide. Stock Photo

RF2TC8P8R–Vinegar fly or fruit fly (Drosophila melanogaster) head detail. Light microscope X150 at 10 cm wide.

Tiny fruit fly (about 2.5mm in length) Drosophila melanogaster Stock Photo

RMT5A5R4–Tiny fruit fly (about 2.5mm in length) Drosophila melanogaster

RMHRHA46–Drosophila Chromosomes, LM

A scanning electron micrograph of a foot of the Drosophila wild type, magnified x975. Stock Photo

RMAMCR51–A scanning electron micrograph of a foot of the Drosophila wild type, magnified x975.

RMA9EHA4–FRUIT FLY DROSOPHILA

RMCT64X5–VIDEO MICROSCOPE

RFD9DT4F–Drosophila SEM

Portrait of a fly: correlative macro photography and scanning electron microscopy. Stock Photo

RMFHYRX7–Portrait of a fly: correlative macro photography and scanning electron microscopy.

. Cytology. Cytology. through this structure of relatively large units by diffusion, as in the case of the oocyte nucleus which appears to be freely permeable to molecules up to the size of proteins. Also in the light of what is known regarding ultrastructure it is not impossible that its permeable properties are subject to considerable variation. A number of electron microscopy. Figure 4-3. Electron Micrograph of Drosophila Salivary Gland Cell Showing Outpocketings (Blebs) of the Nuclear Membrane. Note association of highly differentiated chromosomal material with the developing blebs. Approx Stock Photo

RMPFK9DB–. Cytology. Cytology. through this structure of relatively large units by diffusion, as in the case of the oocyte nucleus which appears to be freely permeable to molecules up to the size of proteins. Also in the light of what is known regarding ultrastructure it is not impossible that its permeable properties are subject to considerable variation. A number of electron microscopy. Figure 4-3. Electron Micrograph of Drosophila Salivary Gland Cell Showing Outpocketings (Blebs) of the Nuclear Membrane. Note association of highly differentiated chromosomal material with the developing blebs. Approx

RMRD3H2A–. Cytology. Cytology. through this structure of relatively large units by diffusion, as in the case of the oocyte nucleus which appears to be freely permeable to molecules up to the size of proteins. Also in the light of what is known regarding ultrastructure it is not impossible that its permeable properties are subject to considerable variation. A number of electron microscopy. Figure 4-3. Electron Micrograph of Drosophila Salivary Gland Cell Showing Outpocketings (Blebs) of the Nuclear Membrane. Note association of highly differentiated chromosomal material with the developing blebs. Approx

Normal vinegar fly or fruit fly (Drosophila melanogaster) complet specimen. Light microscope X50 at 10 cm wide. Stock Photo

RF2TC8P8M–Normal vinegar fly or fruit fly (Drosophila melanogaster) complet specimen. Light microscope X50 at 10 cm wide.

RMHRHA42–Drosophila chromosome, LM

RMA9PT2F–SEM x84 drosophila wild

RMCT6566–VIDEO MICROSCOPE

RMCRYM75–GENETICS RESEARCH

. The Biological bulletin. Biology; Zoology; Marine biology. /3-GALACTOSIDASE IN DROSOPHILA 177. Figure 1. Transmission electron micrograph of the larval midintestine where /3-galactosidase is produced. This micrograph shows the midintestinal epithelium of a larva cut in the transverse plane from a segment of larval midintestine that showed X-gal staining. No evidence of specialized cells containing encapsulated bacteria (mycetocytes) or bacteria was seen within the lumen, m, mitochondria; mv, microvilli; cj, cell junction; 1, lumen of midintestine; er, endoplasmic reticulum. racles, however, Stock Photo

RMRHG7JR–. The Biological bulletin. Biology; Zoology; Marine biology. /3-GALACTOSIDASE IN DROSOPHILA 177. Figure 1. Transmission electron micrograph of the larval midintestine where /3-galactosidase is produced. This micrograph shows the midintestinal epithelium of a larva cut in the transverse plane from a segment of larval midintestine that showed X-gal staining. No evidence of specialized cells containing encapsulated bacteria (mycetocytes) or bacteria was seen within the lumen, m, mitochondria; mv, microvilli; cj, cell junction; 1, lumen of midintestine; er, endoplasmic reticulum. racles, however,