Bactrian camels serve as an important means of transportation in the cold desert regions of
China and Mongolia. Here we present a 2.01 Gb draft genome sequence from both a wild
and a domestic bactrian camel. We estimate the camel genome to be 2.38 Gb, containing
20,821 protein-coding genes. Our phylogenomics analysis reveals that camels shared common
ancestors with other even-toed ungulates about 55–60 million years ago. Rapidly
evolving genes in the camel lineage are significantly enriched in metabolic pathways, and
these changes may underlie the insulin resistance typically observed in these animals. We
estimate the genome-wide heterozygosity rates in both wild and domestic camels to be 1.0
× 10−3. However, genomic regions with significantly lower
heterozygosity are found in the domestic camel, and olfactory receptors are enriched in
these regions. Our comparative genomics analyses may also shed light on the genetic basis of
the camel's remarkable salt tolerance and unusual immune system.
As an important tumor suppressor protein, reactivate mutated p53 was found in many kinds of human cancers and that restoring active p53 would lead to tumor regression. In this work, we developed a new computational method to predict the transcriptional activity for one-, two-, three- and four-site p53 mutants, respectively. With the approach from the general form of pseudo amino acid composition, we used eight types of features to represent the mutation and then selected the optimal prediction features based on the maximum relevance, minimum redundancy, and incremental feature selection methods. The Mathew's correlation coefficients (MCC) obtained by using nearest neighbor algorithm and jackknife cross validation for one-, two-, three- and four-site p53 mutants were 0.678, 0.314, 0.705, and 0.907, respectively. It was revealed by the further optimal feature set analysis that the 2D (two-dimensional) structure features composed the largest part of the optimal feature set and maybe played the most important roles in all four types of p53 mutant active status prediction. It was also demonstrated by the optimal feature sets, especially those at the top level, that the 3D structure features, conservation, physicochemical and biochemical properties of amino acid near the mutation site, also played quite important roles for p53 mutant active status prediction. Our study has provided a new and promising approach for finding functionally important sites and the relevant features for in-depth study of p53 protein and its action mechanism.
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