An electron micrograph of a mouse liver cell

An electron micrograph of a mouse liver cell. Magnification approximately 12,000 times.

electron micrograph, mouse liver cell

  • ID: 16649
  • Source: DNALC.DNAFTB

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16636. Gallery 29: Electron micrograph of chromatin

Electron micrograph of the 10-nm fiber.

  • ID: 16636
  • Source: DNAFTB

16637. Gallery 29: Electron micrograph of chromatin (1)

Electron micrograph of the 30-nm fiber.

  • ID: 16637
  • Source: DNAFTB

16767. Gallery 37: Normal Drosophila Head, electron micrograph

Scanning electron micrograph of the head a normal Drosophila.

  • ID: 16767
  • Source: DNAFTB

16768. Gallery 37: Antennapedia Drosophila Head, electron micrograph

Scanning electron micrograph of the head a Drosophila mutant for the antennapedia gene.

  • ID: 16768
  • Source: DNAFTB

16533. Gallery 24: Electron micrograph of RNA/DNA hybrid

This was one of the original photos that Roberts and his group used for analyzing their results.

  • ID: 16533
  • Source: DNAFTB

16638. Gallery 29: Chromosome with histone stripped

Electron micrograph of the DNA and the protein scaffold left over from one chromosome (insert) with all the histone stripped out.

  • ID: 16638
  • Source: DNAFTB

16627. DNA is packaged in a chromosome.

DNAFTB Animation 29: Roger Kornberg explains his work with Aaron Klug on histones, which bind DNA to form chromatin.

  • ID: 16627
  • Source: DNALC.DNAFTB

16231. Gallery 7: Micrograph of Cell Dividing, 2

(2 of 4) Cell dividing: chromosomes are visible and lined up at the plane of division.

  • ID: 16231
  • Source: DNAFTB

16232. Gallery 7: Micrograph of Cell Dividing, 3

(3 of 4) Cell dividing: chromosomes are being pulled toward the cellular poles.

  • ID: 16232
  • Source: DNAFTB

16540. Video 24: Richard Roberts, clip 4

Describing the set up of the electron micrograph experiments.

  • ID: 16540
  • Source: DNAFTB