Detection of SNPs of T2DM susceptibility genes by a ligase detection reaction-fluorescent nanosphere technique.

OBJECTIVE: To establish a high throughput, low cost, and simple nanotechnology-based method for the detection of single nucleotide polymorphism (SNP) loci in type 2 diabetes mellitus (T2DM). METHODS: Multiplex ligase detection reaction (LDR) amplification was performed using fluorescently labeled magnetic nanosphere-bound upstream LDR probes and downstream probes labeled with a unique fluorescent group for each SNP locus. The amplified LDR products were separated by magnetic nanospheres and then scanned by fluorescence spectroscopy. Four SNP loci associated with T2DM were detected, including the rs13866634 locus in SLC30A8, rs10811661in CDKN2A/2B, rs1111875 in the HHEX gene, and rs7903146 in the TCF7L2 gene. The SNP genotype was also determined by DNA sequencing as a control. RESULTS: The SNP genotypes of the four gene loci determined by the nanosphere-based multiplex LDR method were consistent with the DNA sequencing results. The accuracy rate was 100%. CONCLUSION: A method based on multiplex PCR and LDR was established for simultaneous detection of four SNP loci of T2DM susceptibility genes.

Performance of in silico tools for the evaluation of p16INK4a (CDKN2A) variants in CAGI.

Correct phenotypic interpretation of variants of unknown significance for cancer-associated genes is a diagnostic challenge as genetic screenings gain in popularity in the next-generation sequencing era. The Critical Assessment of Genome Interpretation (CAGI) experiment aims to test and define the state of the art of genotype-phenotype interpretation. Here, we present the assessment of the CAGI p16INK4a challenge. Participants were asked to predict the effect on cellular proliferation of 10 variants for the p16INK4a tumor suppressor, a cyclin-dependent kinase inhibitor encoded by the CDKN2A gene. Twenty-two pathogenicity predictors were assessed with a variety of accuracy measures for reliability in a medical context. Different assessment measures were combined in an overall ranking to provide more robust results. The R scripts used for assessment are publicly available from a GitHub repository for future use in similar assessment exercises. Despite a limited test-set size, our findings show a variety of results, with some methods performing significantly better. Methods combining different strategies frequently outperform simpler approaches. The best predictor, Yang&Zhou lab, uses a machine learning method combining an empirical energy function measuring protein stability with an evolutionary conservation term. The p16INK4a challenge highlights how subtle structural effects can neutralize otherwise deleterious variants.

Antitumor activity of cell-permeable p18(INK4c) with enhanced membrane and tissue penetration.

Practical methods to deliver proteins systemically in animals have been hampered by poor tissue penetration and inefficient cytoplasmic localization of internalized proteins. We therefore pursued the development of improved macromolecule transduction domains (MTDs) and tested their ability to deliver therapeutically active p18(INK4c). MTD103 was identified from a screen of 1,500 signal peptides; tested for the ability to promote protein uptake by cells and tissues; and analyzed with regard to the mechanism of protein uptake and the delivery of biologically active p18(INK4c) into cancer cells. The therapeutic potential of cell-permeable MTD103p18(INK4c) (CP-p18(INK4c)) was tested in the HCT116 tumor xenograft model. MTD103p18(INK4c) appeared to traverse plasma membranes directly, was transferred from cell-to-cell and was therapeutically effective against cancer xenografts, inhibiting tumor growth by 86-98% after 5 weeks (P < 0.05). The therapeutic responses to CP-p18(INK4c) were accompanied by high levels of apoptosis in tumor cells. In addition to enhancing systemic delivery of CP-p18(INK4c) to normal tissues and cancer xenografts, the MTD103 sequence delayed protein clearance from the blood, liver and spleen. These results demonstrate that macromolecule intracellular transduction technology (MITT), enabled by MTDs, may provide novel protein therapies against cancer and other diseases.

In silico structural and functional analysis of fragments of the ankyrin repeat protein p18(INK4c).

Ankyrin repeat proteins (ARPs) are ubiquitous proteins that play critical regulatory roles in organisms and consist of repeating motifs (ankyrin repeats) stacked in non-globular, almost linear, "quasi one-dimensional" configurations. They also have highly unusual mechanical properties, notably ARPs can behave as nano-springs. Both their essential cellular functions and distinctive nano-mechanical properties have aroused interest in ARPs for potential applications in medicine and nanotechnology. Further, the modular architecture of ARPs, which lack the long-range contacts that typically stabilize globular proteins, provides a new paradigm for understanding protein stability and folding mechanisms of proteins. In the present study, the stability of ARP p18INK4c (p18) and fifty p18 fragments was investigated by all- atomic molecular dynamics (MD) simulations in explicit water on a ~3.3 micro- seconds timescale. The fragment simulations indicate that p18 alpha-helices are significantly stabilized by tertiary interactions, because in the absence of their native context they readily melt. All single p18 ARs and their structural elements are also unstable outside their native context. The minimal stable motifs are pairs of ARs, implying that inter-repeat contacts are essential for AR stability. Further, pairs of internal ARs are less stable than pairs that include a native capping AR. The MD simulations also provide indications of the functional roles of p18 turns and loops; the turns appear to be essential for the stability of the protein, while the loops both help to stabilize the p18 structure and are involved in recognition processes. Temperature-induced unfolding analysis shows that the p18 melts from the N-terminus to the C- terminus.

Two C-terminal ankyrin repeats form the minimal stable unit of the ankyrin repeat protein p18INK4c.

Ankyrin repeat proteins (ARPs) appear to be abundant in organisms from all phyla, and play critical regulatory roles, mediating specific interactions with target biomolecules and thus ordering the sequence of events in diverse cellular processes. ARPs possess a non-globular scaffold consisting of repeating motifs named ankyrin (ANK) repeats, which stack on each other. The modular architecture of ARPs provides a new paradigm for understanding protein stability and folding mechanisms. In the present study, the stability of various C-terminal fragments of the ARP p18(INK4c) was investigated by all-atomic 450 ns molecular dynamics (MD) simulations in explicit water solvent. Only motifs with at least two ANK repeats made stable systems in the available timescale. All smaller fragments were unstable, readily losing their native fold and alpha-helical content. Since each non-terminal ANK repeat has two hydrophobic sides, we may hypothesize that at least one hydrophobic side must be fully covered and shielded from the water as a necessary, but not sufficient, condition to maintain ANK repeat stability. Consequently, at least two ANK repeats are required to make a stable ARP.