Biology, Pages 334-346Neil Campbell and Jane Reece's BIOLOGY remains unsurpassed as the most successful majors biology textbook in the world. This text has invited more than 4 million students into the study of this dynamic and essential discipline. |
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Page 2
... coli in this colorized SEM . By injecting its DNA into the cell , the virus sets in motion a genetic takeover of the bacterium . Molecular biology was born in the laboratories of microbiologists studying viruses and bacteria . Microbes ...
... coli in this colorized SEM . By injecting its DNA into the cell , the virus sets in motion a genetic takeover of the bacterium . Molecular biology was born in the laboratories of microbiologists studying viruses and bacteria . Microbes ...
Page 3
... translation . Figure 18.1 T4 bacteriophage infecting an E. coli cell . Beyond their value as model systems , viruses and bacteria have unique genetic mechanisms that are interesting in their own right . These specialized mechanisms have 3.
... translation . Figure 18.1 T4 bacteriophage infecting an E. coli cell . Beyond their value as model systems , viruses and bacteria have unique genetic mechanisms that are interesting in their own right . These specialized mechanisms have 3.
Page 28
... coli cell by phage λ begins when the phage binds to the surface of the cell and injects its DNA ( Figure 18.7 ) . Within the host , the 2 DNA molecule forms a circle . What happens next depends on the reproductive mode : lytic cycle or ...
... coli cell by phage λ begins when the phage binds to the surface of the cell and injects its DNA ( Figure 18.7 ) . Within the host , the 2 DNA molecule forms a circle . What happens next depends on the reproductive mode : lytic cycle or ...
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animal viruses bacterial cell bacterial chromosome bacteriophage bacterium bind to specific capsid cause disease cellular enzymes circular coli cell Cycles of Phages DNA molecule double-stranded emerging viruses enter the host enveloped viruses eukaryotes existing viruses Figure genetic recombination glycoproteins herpesvirus host cell host range host species human disease immune system kill the host lysogenic cycle lytic cycle mechanisms membranous envelope microbes model systems mosaic virus TMV mRNA mutation natural selection favors nucleic acid obligate intracellular parasites particles phage DNA plant to plant plant viruses plasmids plasmodesmata polymerase prions prokaryotic prophage genes protein coat provirus restriction enzymes retrovirus reverse transcriptase RNA viruses Scientists simplest spread stranded RNA symptoms syndrome synthesis temperate phage template tobacco mosaic virus transcribed transposons type of virus vaccines vertical transmission viral diseases viral DNA viral envelope viral genome viral infection viral nucleic acid viral proteins viral reproductive cycle viroids virulent phage viruses and bacteria viruses cause