An analysis of simple computational strategies to facilitate the design of functional molecular information processors

BACKGROUND: Biological macromolecules (DNA, RNA and proteins) are capable of processing physical or chemical inputs to generate outputs that parallel conventional Boolean logical operators. However, the design of functional modules that will enable these macromolecules to operate as synthetic molecular computing devices is challenging. RESULTS: Using three simple heuristics, we designed RNA sensors that can mimic the function of a seven-segment display (SSD). Ten independent and orthogonal sensors representing the numerals 0 to 9 are designed and constructed. Each sensor has its own unique oligonucleotide binding site region that is activated uniquely by a specific input. Each operator was subjected to a stringent in silico filtering. Random sensors were selected and functionally validated via ribozyme self cleavage assays that were visualized via electrophoresis. CONCLUSIONS: By utilising simple permutation and randomisation in the sequence design phase, we have developed functional RNA sensors thus demonstrating that even the simplest of computational methods can greatly aid the design phase for constructing functional molecular devices. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (doi:10.1186/s12859-016-1297-x) contains supplementary material, which is available to authorized users

Molecular characterisation and expression analysis of cathepsin D from the Asian seabass lates calcarifer

The lysosomal aspartic proteinase cathepsin D is an acute phase protein involved in various physiological processes, including vitellogenesis, yolk processing and immune responses. In this study, we characterised the cathepsin D from the Asian seabass Lates calcarifer and examined its expression profile during infection. The complete coding sequence of L. calcarifer cathepsin D consists of 1191 nucleotides, encoding a 396 amino acid protein molecule that is made up of a putative signal peptide, a leader peptide and a mature peptide. Phylogenetic analyses showed that two types of cathepsin D are present in the teleost lineage i.e. cathepsin D1 and D2, whereas higher vertebrates possess only one type of cathepsin D. L. calcarifer cathepsin D was clustered together with cathepsin D1 from other teleosts. Compared to mammalian sequences, L. calcarifer cathepsin D lacks the β-hairpin loop that forms the double chain and is present as a single chain peptide with conserved aspartic active sites like other fish. Both multiple sequence alignment and phylogenetic analysis indicated that the L. calcarifer cathepsin D sequence codes for cathepsin D1 and suggested that it shares the same functions with cathepsin D from other fish. Expression profiling analysis of cathepsin D in L. calcarifer infected with Aeromonas hydrophila showed that it is up-regulated in immune-related tissues such as gills, spleen and liver, suggesting that cathepsin D plays an important role in the innate immune response of L. calcarifer against pathogens

Additional file 1: of An analysis of simple computational strategies to facilitate the design of functional molecular information processors

S1. The truth table of seven-segment character display. Alphabets (a-g) represent the seven segment of SSD. Each of the digits will be displayed based on the combination of current flows in the seven segments. S2. Input oligonucleotides (first strategy). Input sequences to activate the respective sensors generated from the first strategy. S3. Input oligonucleotides (second strategy). Input sequences to activate the respective sensors generated from the second strategy. (DOC 44 kb