[Bioinformatic analysis of pygo1 gene in Homo sapiens].

OBJECTIVE: To analyze the structure and function of PYGO1 protein with bioinformatics. METHODS: The bioinformatic methods and tools were used to analyze the physical and chemical properties, transmembrane region, hydrophobicity and hyrdrophilicity, secondary structure and functional category of PYGO1 protein. RESULTS: The bioinformatic analysis revealed that proline content was the highest of all amino acid residues in PYGO1 protein; the molecular formula was C(1943)H(2937)N(577)O(635)S(18) with a relative molecular mass of 45; and the theoretical isoelectric point was 6.38. The analysis also demonstrated that PYGO1 was a hydrophilic and non-transmembrane protein; its main component was alpha-helix and random coil; it contained a plant homeodomain. CONCLUSION: Human pygo1 gene may act as a transcription regulation factor to regulate the heart development and the progress of heart diseases.

Investigation of single nucleotide polymorphisms based on the intronic sequences of the propylene alcohol dehydrogenase gene in Chinese tobacco genotypes.

A pair of primers was designed to amplify the propylene alcohol dehydrogenase gene sequence based on the cDNA sequence of the tobacco allyl-alcohol dehydrogenase gene. All introns were sequenced using traditional polymerase chain reaction (PCR) methods and T-A cloning. The sequences from common tobacco (Nicotiana tabaccum L.) and rustica tobacco (Nicotiana rustica L.) were analysed between the third intron and the fourth intron of the propylene alcohol dehydrogenase gene. The results showed that the alcohol dehydrogenase gene is a low-copy nuclear gene. The intron sequences have a combination of single nucleotide polymorphisms and length polymorphisms between common tobacco and rustica tobacco, which are suitable to identify the different germplasms. Furthermore, there are some single nucleotide polymorphism sites in the target sequence within common tobacco that can be used to distinguish intraspecific varieties.

[Chloroplast genetic engineering: a new approach in plant biotechnology].

Chloroplast genetic engineering, offers several advantages over nuclear transformation, including high level of gene expression, increased biosafety, remedying some limitations associated with nuclear genetic transformation, such as gene silencing and the stability of transformed genes. It is now regarded as an attractive new transgenic technique and further development of biotechnology in agriculture. In this article we reviewed the characteristics, applications of chloroplast genetic engineering and its promising prospects were discussed.