Signals in the promoter regions of several cancerous genes.

The eukaryotic core promoter regions are complex and fuzzy, usually lacking any conserved regions. However, they contain signals in the form of short stretches of nucleic acid sequences, for transcription start sites (TSS) that are recognized by the transcription factors (TFs). The core promoter region thus plays an important role in biological pathways (gene network and activation). It has been reported that these signals are composed of nucleotide hexamers in the promoter sequence (smaller sequences are likely to have too little information to be useful and longer sequences are too complex to be recognized by proteins) reasonably close to the TSS. The signals (nucleotide hexamers) have been identified by a similarity search on the eukaryotic promoter database (EPD, Homo sapiens). The signals have been classified, depending on their base composition. They have been have clustered using an algorithm, such that there are two and three nucleotide differences between the classes and a single nucleotide difference within a class. We have reclassified the hexamers taking the highest frequent hexamers present in the EPD (Homo sapiens) as the class representatives. Also we have tried to find whether the same composition is reflected on the miRNAs but found that they probably have other functions unrelated to promoter recognition. In this report melanoma carcinoma pathway has been chosen as the reference pathway and the promoters of the driver genes has been searched for the presence of the major classes. A few of these were found and are reported here. Several non-cancerous genes have also been studied as reference and comparison.

Synonymous codon usage in different protein secondary structural classes of human genes: implication for increased non-randomness of GC3 rich genes towards protein stability.

The relationship between the synonymous codon usage and different protein secondary structural classes were investigated using 401 Homo sapiens proteins extracted from Protein Data Bank (PDB). A simple Chi-square test was used to assess the significance of deviation of the observed and expected frequencies of 59 codons at the level of individual synonymous families in the four different protein secondary structural classes. It was observed that synonymous codon families show non-randomness in codon usage in four different secondary structural classes. However,when the genes were classified according to their GC3 levels there was an increase in non-randomness in high GC3 group of genes. The non-randomness in codon usage was further tested among the same protein secondary structures belonging to four different protein folding classes of high GC3 group of genes. The results show that in each of the protein secondary structural unit there exist some synonymous family that shows class specific codon-usage pattern. Moreover, there is an increased non-random behaviour of synonymous codons in sheet structure of all secondary structural classes in high GC3 group of genes. Biological implications of these results have been discussed.