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Published Papers
| Independent Functions of Viral Protein and Nucleic Acid in Growth of Bacteriophage. September 20, 1952. |
Page 17 [55]
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Authors: Martha Chase, Alfred Hershey
![Page 17 [55]](hersheychase-pg17-xl.jpg "Page 17 [55]")
Page 17 [55]
| Title: |
Independent Functions of Viral Protein and Nucleic Acid in Growth of Bacteriophage [17 of 18] |
| Creator: |
Chase, Martha |
| Contributor: |
Hershey, Alfred Day, 1908 |
| Publisher: |
Journal of General Physiology |
| Date: |
1952-09-20 |
| Subject: |
Molecular biology
Molecular genetics
|
| Description: |
From the Journal of General Physiology Vol. 36, No. 1. |
| Type: |
Text |
| Format: |
text/plain |
| Language: |
en |
| Identifier: |
hersheychase-pg17.jpg |
| Source: |
Master scanned with Epson GT-10000+ flatbed scanner at 600 dpi. |
| Rights: |
http://osulibrary.orst.edu/specialcollections/coll/pauling/dna/copyright.html |
| Full Text: |
A. D. HERSEY AND MARTHA CHASE 55
the phage DNA in a form not precipitable by antiserum and not adsorbable
to bacteria. The sulfur-containing protein of the phage particle evidently
makes up a membrane that protects the phage DNA from DNase, comprises
the sole or principal antigenic material, and is responsible for attachment of
the virus to bacteria.
2. Adsorption of T2 to heat-killed bacteria, and heating or alternate freezing
and thawing of infected cells, sensitize the DNA of the adsorbed phage to
DNase. These treatments have little or no sensitizing effect on unadsorbed
phage. Neither heating nor freezing and thawing releases the phage DNA
from infected cells, although other cell constituents can be extracted by these
methods. These facts suggest that the phage DNA forms part of an organized
intracellular structure throughout the period of phage growth.
3. Adsorption of phage T2 to bacterial debris causes part of the phage
DNA to appear in solution, leaving the phage sulfur attached to the debris.
Another part of the phage DNA, corresponding roughly to the remaining half
of the DNA of the inactivated phage, remains attached to the debris but can
be separated from it by DNase. Phage T4 behaves similarly, although the
two phages can be shown to attach to different combining sites. The inactiva-
tion of phage by bacterial debris is evidently accompanied by the rupture of
the viral membrane.
4. Suspensions of infected cells agitated in a Waring blendor release 75 per
cent of the phage sulfur and only 15 per cent of the phage phosphorus to the
solution as a result of the applied shearing force. The cells remain capable of
yielding phage progeny.
5. The facts stated show that most of the phage sulfur remains at the cell
surface and most of the pliage DNA enters the cell on infection. Whether
sulfur-free material other than DNA enters the cell has not been determined.
The properties of the sulfur-containing residue identify it as essentially un-
changed membranes of the phage particles. All types of evidence show that
the passage of phage DNA into the cell occurs in non-nutrient medium under
conditions in which other known steps in viral growth do not occur.
6. The phage progeny yielded by bacteria infected with phage labeled
with radioactive sulfur contain less than 1 per cent of the parental radioactiv-
ity. The progeny of phage particles labeled with radioactive phosphorus con-
tain 30 per cent or more of the parental phosphorus.
7. Phage inactivated by dilute formaldehyde is capable of adsorbing to
bacteria, but does not release its DNA to the cell. This shows that the inter-
action between phage and bacterium resulting in release of the phage DNA
from its protective membrane depends on labile components of the phage
particle. By contrast, the components of the bacterium essential to this inter-
action are remarkably stable. The nature of the interaction is otherwise un-
known.
R. The sulfur-containing protein of resting phage particles is confined to a
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