Genetic code correlations: Amino acids and their anticodon nucleotides

Summary The data here show direct correlations between both the hydrophobicity and the hydrophilicity of the homocodonic amino acids and their anticodon nucleotides. While the differences between properties of uracil and cytosine derivatives are small, further data show that uracil has an affinity for charged species. Although these data suggest that molecular relationships between amino acids and anticodons were responsible for the origin of the code, it is not clear what the mechanism of the origin might have been.     

Genetic code preferentially conserves long-range interactions among the amino acids

The physical properties of amino acids were investigated in order to evaluate their possible relationship to the assignment of codons for amino acids in the genetic code. A comparison of the interconversion probability between amino acids and the distances between the amino acids for individual physical properties revealed a striking hierarchy among the physical properties. Surprisingly, it is the long-range/solvent interactions and not the short-range/stereochemical properties which are preferentially conserved in the genetic code.     

Comparative rates of esterification of 5′-AMP with hydrophobic amino acids: Relevance to the genetic-code assignments

We have continued our program aimed at understanding the origin and evolution of the genetic code and the process of protein synthesis by comparing the rates of esterification of 5'-AMP by a series of hydrophobic N-acetylamino acids. The reaction clearly shows differences in reaction rate (AcPhe greater than AcLeu greater than AcVal greater than AcIle) among the amino acids having A as middle letter of their anticodons. However, there were no significant differences in reaction rate between AcLeu, AcNorleu, and Ac-alpha-aminobutyric acid, and AcGly reacted faster than all of these and AcPhe. Consequently, this simple reaction with AMP can distinguish only among those amino acids that actually have A as the middle anticodonic nucleotide. The relevance of these studies to the origins of the process of protein synthesis and of the genetic code is discussed in conjunction with results from other studies of a similar nature.     

Design of proteins with hydrophobic and polar amino acids

A two amino acid (hydrophobic and polar) scheme is used to perform the design on target conformations corresponding to the native states of 20 single chain proteins. Strikingly, the percentage of successful identification of the nature of the residues benchmarked against naturally occurring proteins and their homologues is around 75%, independent of the complexity of the design procedure. Typically, the lowest success rate occurs for residues such as alanine that have a high secondary structure functionality. Using a simple lattice model, we argue that one possible shortcoming of the model studied may involve the coarse-graining of the 20 kinds of amino acids into just two effective types. Proteins 32:80–87, 1998. © 1998 Wiley-Liss, Inc.     

Digital coding of amino acids based on hydrophobic index

Analysis of amino acid sequences can provide useful insights into the tertiary structures of proteins and their biological functions. One of the critical problems in amino acid analysis is how to establish a digital coding system to better reflect the properties of amino acids and their degeneracy. Based on the hydrophobic index, a one-to-one relationship has been established between the amino acid sequence and the digital signal process. Such a "bridge" will make it possible to apply all the existing powerful methods in the signal processing area to analysis of the amino acid sequences.     

The distribution of amino acids in the genetic code

By introducing a mutational deterioration functionMD and a principle of approximate minimum of the function, we have deduced the distribution of amino acids in genetic code, which includes the degenracy rule of codons, the global extreme of genetic code from codon interactions and the hydrophobicity domain of the prevalent (standard) code.The project supported by National Science Foundation of China.     

Preceding hydrophobic and beta-branched amino acids attenuate splicing by the CnePRP8 intein

As the Cne PRP8 intein is active and exists in an essential gene of an important fungal pathogen, inhibitors of splicing and assays for intein activity are of interest. The self-splicing activity of Cne PRP8, the intein from the Prp8 gene of Cryptococcus neoformans, was assessed in different heterologous fusion proteins expressed in Escherichia coli. Placement of a putatively inactive variant of the intein adjacent to the alpha-complementation peptide abolished the peptide's ability to restore beta-galactosidase activity, while an active variant allowed complementation. This alpha-complementation peptide therefore provides a facile assay of splicing which can be used to test potential inhibitors. When placed between two heterologous protein domains, splicing was impaired by a beta-branched amino acid immediately preceding the intein, while splicing occurred only with a hydroxyl or thiol immediately following the intein. Both these assays sensitively report impairment of splicing and provide information on how context constrains the splicing ability of Cne PRP8.     

Recognition of amino acids in solution: The role of the hydrophobic forces

Theoretical results for molecular structures and solvation clusters have been used for an interpretation of the experimental observations on the selectivity of an amino acid-sensitive cell in the adult Colorado beetle. As a consequence, it is postulated that strong polar interactions (involving the charged groups-NH ₃ ⁺ and -COO^–), given the appropriate steric conditions, make the determining contribution toward the anchoring of the substrate to the receptor, while the hydrophobic forces are responsible for the specificity.     

The structural code for proteins: zonal distribution of amino acid residues and stabilization of helices by hydrophobic triplets

The general distribution of 2259 amino acid residues in α-helical and in non-helical regions has been calculated using data from 12 proteins. The irregular distribution of hydrophobic residues in the helical parts of the sample permits classification of the helical regions in hydrophobic-clustered and hydrophobic-depleted zones. In comparison with the composition of α-helices, Ala, Leu, Val, Ile and Tyr predominate in hydrophobic-clustered zones, whereas Cys and Gln tend to accumulate in hydrophobic-depleted zones. The N-terminal part of the helices is rich in Asp and Pro and poor in Leu and His, whereas the C-terminal is rich in Lys and Gin and does not contain Pro.For helical regions, hydrophobic residues, located along the sequence with a relation of 1-2-5 or 1-4-5, are more frequent than those with a relation of 1-2-3, 1-2-4, 1-3-4 or 1-3-5. The opposite is found for non-helical regions. All these deviations are statistically significant. It is concluded that hydrophobic triplets 1-2-5 and 1-4-5 are required for stabilizing the helices.The relevance of our results, and others reported in the bibliography, towards a better understanding of the structural code for proteins is discussed.     

Simplification of the genetic code: restricted diversity of genetically encoded amino acids

At earlier stages in the evolution of the universal genetic code, fewer than 20 amino acids were considered to be used. Although this notion is supported by a wide range of data, the actual existence and function of the genetic codes with a limited set of canonical amino acids have not been addressed experimentally, in contrast to the successful development of the expanded codes. Here, we constructed artificial genetic codes involving a reduced alphabet. In one of the codes, a tRNA^Ala variant with the Trp anticodon reassigns alanine to an unassigned UGG codon in the Escherichia coli S30 cell-free translation system lacking tryptophan. We confirmed that the efficiency and accuracy of protein synthesis by this Trp-lacking code were comparable to those by the universal genetic code, by an amino acid composition analysis, green fluorescent protein fluorescence measurements and the crystal structure determination. We also showed that another code, in which UGU/UGC codons are assigned to Ser, synthesizes an active enzyme. This method will provide not only new insights into primordial genetic codes, but also an essential protein engineering tool for the assessment of the early stages of protein evolution and for the improvement of pharmaceuticals.     

Hydropathic anti-complementarity of amino acids based on the genetic code

An interesting pattern in the genetic code has been discovered. Codons for hydrophilic and hydrophobic amino acids on one strand of DNA are complemented by codons for hydrophobic and hydrophilic amino acids on the other DNA strand, respectively. The average tendency of codons for "uncharged" (slightly hydrophilic) amino acids is to be complemented by codons for "uncharged" amino acids.     

Cyanamide mediated syntheses of peptides containing histidine and hydrophobic amino acids

Summary Using the model of a primitive earth evaporation pond, the synthesis of three histidyl peptides in yields of up to 11% was demonstrated when aqueous solutions of histidine, leucine, ATP, cyanamide, and MgCl₂ were evaporated and heated for 24 h at 80°C. In addition, peptides were formed in yields of up to 56%, 35%, and 21%, respectively for phenylalanine, leucine, and alanine when aqueous solutions of the appropriate amino acid were evaporated and heated with cyanamide and one or more of the following components: ATP, AMP, 4-amino-5-imidazole carboxamide, or MgCl₂. The greatest peptide yield occurred at pH 3. But peptide formation was demonstrated for a system of Leu, cyanamide, and MgCl₂ adjusted to pH 7 with NH₄OH.Peptide synthesis was also studied in the presence of CaCl₂, ZnCl₂, different adenosine nucleotides, and UTP to compare their effects on peptide synthesis. The optimum conditions for cyanamide mediated peptide synthesis were also studied in terms of pH, reaction time, reaction temperature, and cyanamide concentration. The major side product in nearly all reactions studied appears to be an amino acid-cyanamide adduct. Peptides were analyzed and identified by thin layer chromatography, acid hydrolysis, and enzymatic degradation.     

Role of hydrophobic amino acids in gurmarin,a sweetness-suppressing polypeptide

The sweetness-suppressing polypeptide gurmarin isolated from Gymnema sylvestre consists of 35 amino acid residues and contains three intramolecular disulfide bonds. Nuclear magnetic resonance analysis showed that the hydrophobic side chains of Tyr-13, Tyr-14, Trp-28, and Trp-29 in gurmarin are oriented outwardly. Together with the hydrophobic side chains of Leu-9, Ile-11, and Pro-12, they form a hydrophobic cluster, and therefore these hydrophobic groups are assumed to act as the site for interaction with the receptor protein. To examine the roles of these hydrophobic amino acids, they were replaced by Gly. The resulting [Gly^13,14,28,29]gurmarin and [Gly^{9,11,13,14,28,29}]gurmarin did not suppress the responses to sucrose, glucose, fructose, or Gly. This result strongly suggests that these hydrophobic amino acids are involved in the interaction with the receptor protein. © 1998 John Wiley & Sons, Inc. Biopoly 45: 231–238, 1998     

Genetic code: codon bases--the symbols of amino acid synthesis and catabolism pathways

The correlations between genetic codes of amino acids and pathways of synthesis and catabolism of carbon backbone of amino acids are considered. Codes of amino acids which are synthesized from oxoacids of glycolysis, the Krebs cycle and glyoxalic cycle via transamination without any additional chemical reactions, are initiated with guanine (alanine, glutamic and aspartic acids, glycine). Codons of amino acids which are formed on the branches of glycolysis at the level of compounds with three carbon atoms, begin with uracil (phenylalanine, serine, leucine, tyrosine, cysteine, tryptophan). Codes of amino acids formed from aspartate begin with adenine (methionine, isoleucine, threonine, asparagine, lysine, serine), while those of the amino acids formed from the compounds with five carbon atoms (glutamic acid and phosphoribosyl pyrophosphate) begin with cytosine (arginine, proline, glutamine, histidine). The second letter of codons is linked to catabolic pathways of amino acids: most of amino acids entering glycolysis and the Krebs cycle through even-numbered carbon compounds, have adenine and uracil at the second position of codes (A-U type); most of amino acids entering the glycolysis and the Krebs cycle via odd-numbered carbon compounds, have codons with guanine and cytidine at the second position (G-C type). The usage of purine and pyrimidine as the third letter of weak codones in most of amino acids is linked to the enthropy of amino acid formation. A hypothesis claiming that the linear genetic code was assembled from the purine and pyrimidine derivatives which have acted as participants of primitive control of amino acid synthesis and catabolism, is suggested.