Algae, Tree, Herbs, Bush, Shrub, Grasses, Vines, Fern, Moss, Spermatophyta, Bryophyta, Fern Ally, Flower, Photosynthesis, Eukaryote, Prokaryote, carbohydrate, vitamins, amino acids, botany, lipids, proteins, cell, cell wall, biotechnology, metabolities, enzymes, agriculture, horticulture, agronomy, bryology, plaleobotany, phytochemistry, enthnobotany, anatomy, ecology, plant breeding, ecology, genetics, chlorophyll, chloroplast, gymnosperms, sporophytes, spores, seed, pollination, pollen, agriculture, horticulture, taxanomy, fungi, molecular biology, biochemistry, bioinfomatics, microbiology, fertilizers, insecticides, pesticides, herbicides, plant growth regulators, medicinal plants, herbal medicines, chemistry, cytogenetics, bryology, ethnobotany, plant pathology, methodolgy, research institutes, scientific journals, companies, farmer, scientists, plant nutrition
Select Language:
 
   
 
 
Can't find? Try Deep Search with ePlantScience.com  
 
Share |
 
   
Main Menu
If navigation gets difficult, please click the main subject or sitemap to get the list of sub-categories
 
 
 
 
 
Related websites
 
 
 
 
 
 
 
 
Section: Genetics » The Genetic Code
 
 
If you like this page, please click:  
 
 
  The Genetic Code
 
     
 
Content
The Genetic Code
Properties of genetic code 
Chain initiation and chain termination codons
Synonym codons and degeneracy
Mutations and the genetic code 
Wobble hypothesis
New genetic codes in mitochondria and ciliate protozoa
Suppressor mutations, base substitutions and suppressor tRNAs
Second genetic code, and second half of the genetic code
Recoding of the genetic code


In Chemistry of the Gene 1.  Nucleic Acids and Their Structure, it has been shown that all genetic information is stored in the nucleic acids (DNA or RNA). As will be shown later in Expression of Gene : Protein Synthesis 2.  Transcription in Prokaryotes and Eukaryotes, it is also known that the genetic information in the nucleic acids is expressed through synthesis of proteins. As we know, while proteins have 20 different kinds of essential amino acids, nucleic acid (particularly in living cells) has only four different kinds of bases. (Recently, it has been shown that in artificially synthesized DNA segments, the number of bases can extend to more than four i.e. 6 or 8). It may therefore, be realized that while 20 amino acids are the alphabets of the language of proteins, four bases are the alphabets of the language of nucleic acids. Since it is through mRNA (messenger RNA, see Expression of Gene : Protein Synthesis 2.  Transcription in Prokaryotes and Eukaryotes) that the genetic information is passed on to proteins, the problem of genetic code was to prepare a dictionary for translating the language of RNA into the language of proteins. Since one is four alphabet language and the other has 20 alphabets, as shown in Figure 30.1, a singlet code would give only four codons, a doublet code would have 16 codons and triplet code would give us 64 (4 x 4 x 4) triplets. The 64 triplets would be enough to code for 20 amino acids.

In a 64-codons dictionary, either there should be more than one triplets coding for the same amino acid or else, of the 64 triplets, 44 triplets should mean nothing (nonsense). It has now been proved by experimental evidence that the code is triplet and that all 64 codons carry some meaning, although three of these 64 triplets cannot be translated in terms of amino acids, since they mean stop signals. Whenever any one of these three triplets is encountered on mRNA, it orders that the end of the polypeptide chain has reached and that the chain should now be released, before further synthesis may take place.
  
A singlet code, a doublet code and a triplet code.
Fig. 30.1. A singlet code, a doublet code and a triplet code.
 
     






     
     
 
 
     
 
Copyrights 2009 © ePlantScience.com