DNA melting analysis: application of the "open tube" format for detection of mutant KRAS

High-resolution melting (HRM) analysis is a very effective method for genotyping and mutation scanning that is usually performed just after PCR amplification (the “closed tube” format). Though simple and convenient, the closed tube format makes the HRM dependent on the PCR mix, not generally optimal for DNA melting analysis. Here, the “open tube” format, namely the post-PCR optimization procedure (amplicon shortening and solution chemistry modification), is proposed. As a result, mutation scanning of short amplicons becomes feasible on a standard real-time PCR instrument (not primarily designed for HRM) using SYBR Green I. This approach has allowed us to considerably enhance the sensitivity of detecting mutant KRAS using both low- and high-resolution systems (the Bio-Rad iQ5–SYBR Green I and Bio-Rad CFX96–EvaGreen, respectively). The open tube format, though more laborious than the closed tube one, can be used in situations when maximal sensitivity of the method is needed. It also permits standardization of DNA melting experiments and the introduction of instruments of a “lower level” into the range of those suitable for mutation scanning.     

Development of a DNA sensor using a molecular logic gate

This communication reports the increase in fluorescence resonance energy transfer (FRET) efficiency between two laser dyes in the presence of deoxyribonucleic acid (DNA). Two types of molecular logic gates have been designed where DNA acts as input signal and fluorescence intensity of different bands are taken as output signal. Use of these logic gates as a DNA sensor has been demonstrated.     

Tail variation of the folding primer affects the SmartAmp2 process differently

Folding primer (FP), together with turn-back primer (TP) and boost primer (BP), is one of the major components of SmartAmp2, a rapid amplification-based method for SNP detection. FP has a unique design where the annealing region is combined with a tail that can fold back. FP tails can be classified as either “strong” or “weak”, depending on the melting temperature and free energy of the hairpin structure. We report that FP tails affect the amplification process differently; by changing the FP concentration, we can increase the amplification reaction speed with “strong tails”. Unlike “strong tails”, concentration change of FP with “weak tails” did not show significant impact on the amplification speed. The comparative analyses using gel electrophoresis demonstrate that the FP type and FP ratio in the reaction change the amplification pattern. The above observations can be used to optimize the reaction and manipulate the reaction speed of SmartAmp2.     

Amino-terminal domain interactions of lambda integrase on arm-type DNA

In contrast to the other tyrosine recombinase family members, integrase protein (Int) of bacteriophage λ has an additional amino-terminal domain that binds to “arm-type” DNA sequences distant from those involved in strand exchange. The homomeric interaction between neighboring amino-terminal domains of Int is contributed by R30-D71 salt-bridge in a non-equivalent manner on Holliday-junction intermediates. In this report, R30 and D71 residues were investigated in regard to Int’s cooperative binding to “arm-type” DNA and the attenuating function of “arm-type” DNA. The results suggest the electrostatic interaction between residues 30 and 71 is dependent on “arm-type” DNA and contributes the “selective” inhibition of catalytic activity of λ Int by “arm-type” DNA.     

Research progress in the detection of common foodborne hazardous substances based on functional nucleic acids biosensors

With the further improvement of food safety requirements, the development of fast, highly sensitive, and portable methods for the determination of foodborne hazardous substances has become a new trend in the food industry. In recent years, biosensors and platforms based on functional nucleic acids, along with a range of signal amplification devices and methods, have been established to enable rapid and sensitive determination of specific substances in samples, opening up a new avenue of analysis and detection. In this paper, functional nucleic acid types including aptamers, deoxyribozymes, and G-quadruplexes which are commonly used in the detection of food source pollutants are introduced. Signal amplification elements include quantum dots, noble metal nanoparticles, magnetic nanoparticles, DNA walkers, and DNA logic gates. Signal amplification technologies including nucleic acid isothermal amplification, hybridization chain reaction, catalytic hairpin assembly, biological barcodes, and microfluidic system are combined with functional nucleic acids sensors and applied to the detection of many foodborne hazardous substances, such as foodborne pathogens, mycotoxins, residual antibiotics, residual pesticides, industrial pollutants, heavy metals, and allergens. Finally, the potential opportunities and broad prospects of functional nucleic acids biosensors in the field of food analysis are discussed.     

The distribution of the coalescence time and the number of pairwise nucleotide differences in a model of population divergence or speciation with an initial period of gene flow

This paper is concerned with a model of “isolation with an initial period of migration”, where a panmictic ancestral population split into n descendant populations which exchanged migrants symmetrically at a constant rate for a period of time and subsequently became completely isolated. In the limit as the population split occurred an infinitely long time ago, the model becomes an “isolation after migration” model, describing completely isolated descendant populations which arose from a subdivided ancestral population. The probability density function of the coalescence time of a pair of genes and the probability distribution of the number of pairwise nucleotide differences are derived for both models. Whilst these are theoretical results of interest in their own right, they also give an exact analytical expression for the likelihood, for data consisting of the numbers of nucleotide differences between pairs of DNA sequences where each pair is at a different, independent locus. The behaviour of the distribution of the number of pairwise nucleotide differences under these models is illustrated and compared to the corresponding distributions under the “isolation with migration” and “complete isolation” models. It is shown that the distribution of the number of nucleotide differences between a pair of DNA sequences from different descendant populations in the model of “isolation with an initial period of migration” can be quite different from that under the “isolation with migration model”, even if the average migration rate over time (and hence the total number of migrants) is the same in both scenarios. It is also illustrated how the results can be extended to other demographic scenarios that can be described by a combination of isolated panmictic populations and “symmetric island” models.     

A biomolecular implementation of logically reversible computation with minimal energy dissipation

Energy dissipation associated with logic operations imposes a fundamental physical limit on computation and is generated by the entropic cost of information erasure, which is a consequence of irreversible logic elements. We show how to encode information in DNA and use DNA amplification to implement a logically reversible gate that comprises a complete set of operators capable of universal computation. We also propose a method using this design to connect, or 'wire', these gates together in a biochemical fashion to create a logic network, allowing complex parallel computations to be executed. The architecture of the system permits highly parallel operations and has properties that resemble well known genetic regulatory systems.     

Evolutionary implications of error amplification in the self-replicating and protein-synthesizing machinery

Summary Evolutionary constraints operating on animal mitochondrial tRNA were estimated to be reduced to about 1/30 of those that apply to cytoplasmic tRNA. In the nuclear-cytoplasmic system, an effect of a mutation tRNA is likely to be amplified through positive feedback loops consisting of DNA polymerases, RNA polymerases, ribosomal proteins, aminoacyl-tRNA synthetases, tRNA processing enzymes, and others. This amplification phenomenon is called an error cascade and the loops that cause it are called error loops. The freedom of evolutionary change of cytoplasmic tRNA is expected to be severely restricted to avoid the error cascade. In fact, cytoplasmic tRNA is highly conserved during evolution. On the other hand, in the animal mitochondrial system, all of the proteins involved in error loops are coded for in the nuclear genome and imported from the cytoplasm, and accordingly the system is free from the error cascade. The difference in constraints operating on animal tRNA between cytoplasm and mitochondria is attributed to the presence or absence of error loops. It is shown that the constraints on mitochondrial tRNA in fungi are not as relaxed as those in animals. This observation is attributed to the presence of an error loop in fungal mitochondria, since at least one protein of the mitochondrial ribosome is coded for in the mitochondrial genome of fungi. The evolutionary rates of proteins involved in the processing of genetic information are discussed in relation to the error cascade.A preliminary version of this paper was presented at the International tRNA Workshop (Hakone, Japan, March 1983) and at the Second International Colloquium on Endocytobiology (Tübingen, FRG, April 1983)     

Sensitive isothermal detection of nucleic-acid sequence by primer generation–rolling circle amplification

A simple isothermal nucleic-acid amplification reaction, primer generation–rolling circle amplification (PG–RCA), was developed to detect specific nucleic-acid sequences of sample DNA. This amplification method is achievable at a constant temperature (e.g. 60°C) simply by mixing circular single-stranded DNA probe, DNA polymerase and nicking enzyme. Unlike conventional nucleic-acid amplification reactions such as polymerase chain reaction (PCR), this reaction does not require exogenous primers, which often cause primer dimerization or non-specific amplification. Instead, ‘primers’ are generated and accumulated during the reaction. The circular probe carries only two sequences: (i) a hybridization sequence to the sample DNA and (ii) a recognition sequence of the nicking enzyme. In PG–RCA, the circular probe first hybridizes with the sample DNA, and then a cascade reaction of linear rolling circle amplification and nicking reactions takes place. In contrast with conventional linear rolling circle amplification, the signal amplification is in an exponential mode since many copies of ‘primers’ are successively produced by multiple nicking reactions. Under the optimized condition, we obtained a remarkable sensitivity of 84.5 ymol (50.7 molecules) of synthetic sample DNA and 0.163 pg (~60 molecules) of genomic DNA from Listeria monocytogenes, indicating strong applicability of PG–RCA to various molecular diagnostic assays.     

Epigenomic communication systems in humans and honey bees: From molecules to behavior

A 2010 Nature editorial entitled “Time for the Epigenome” trumpets the appearance of the International Human Epigenome Consortium and likens it to Biology's equivalent of the Large Hadron Collider. It strongly endorses the viewpoint that selective modifications of “marks” on DNA and histones constitute the crucial codes of life, a proposition which is hotly contested (Ptashne et al., in 2010). This proposition reflects the current mindset that DNA and histone modifications are the prime movers in gene regulation during evolution. This claim is perplexing, since the well characterized organisms, Drosophila melanogaster and Caenorhabditis elegans, lack methylated DNA “marks” and the DNA methytransferase enzymology. Despite their complete absence, D. melanogaster nevertheless has extensive gene regulatory networks which drive sophisticated development, gastrulation, migration of germ cells and yield a nervous system with significant neural attributes. In stark contrast, the honey bee Apis mellifera deploys its human-type DNA methyltransferase enzymology to “mark” its DNA and it too has sophisticated development. What roles therefore is DNA methylation playing in different animals? The honey bee brings a fresh perspective to this question. Its combinatorial chemistry of pheromones, tergal and cuticular exudates provide an exquisite communication system between thousands of individuals. The development of queen and worker is strictly controlled by differential feeding of royal jelly and their adult behaviors are accompanied by epigenomic changes. Their interfaces with different “environments” are extensive, allowing an evaluation of the roles of epigenomes in behavior in a natural environment, in the space of a few weeks, and at requisite levels of experimental rigor.     

The sense of water in the blowfly Protophormia terraenovae

The gustatory system of the blowfly, Protophormia terraenovae, is a relatively simple biological model for studies on chemosensory input and behavioral output. It appears to have renewed interest as a model for studies on the role of water channels, namely aquaporins or aquaglyceroporins, in water detection. To this end, we investigated the presence of water channels, their role in “water” and “salt” cell responsiveness and the transduction mechanism involved. For the first time our electrophysiological results point to the presence of an aquaglyceroporin in the chemoreceptor membrane of the “water” cell in the blowfly taste chemosensilla whose transduction mechanism ultimately involves an intracellular calcium increase and consequently cell depolarization. This hypothesis is also supported by calcium imaging data following proper stimulation. This mechanism is triggered by “water” cell stimulation with hypotonic solutions and/or solutes such as glycerol which crosses the membrane by way of aquaglyceroporins. Behavioral output indicates that the “sense” of water in blowflies is definitely not dependent on the “water” cell only, but also on the “salt” cell sensitivity. These findings also hypothesize a new role for aquaglyceroporin in spiking cell excitability.     

A Novel Bio-Sensor Based on DNA Strand Displacement

DNA strand displacement technology performs well in sensing and programming DNA segments. In this work, we construct DNA molecular systems based on DNA strand displacement performing computation of logic gates. Specifically, a class of so-called “DNA neurons” are achieved, in which a “smart” way inspired by biological neurons encoding information is developed to encode and deliver information using DNA molecules. The “DNA neuron” is bistable, that is, it can sense DNA molecules as input signals, and release “negative” or “positive” signals DNA molecules. We design intelligent DNA molecular systems that are constructed by cascading some particularly organized “DNA neurons”, which could perform logic computation, including AND, OR, XOR logic gates, automatically. Both simulation results using visual DSD (DNA strand displacement) software and experimental results are obtained, which shows that the proposed systems can detect DNA signals with high sensitivity and accretion; moreover, the systems can process input signals automatically with complex nonlinear logic. The method proposed in this work may provide a new way to construct a sensitive molecular signal detection system with neurons spiking behavior in vitro, and can be used to develop intelligent molecular processing systems in vivo.     

Stable Intermediates and Holdpoints in the Rapid Differentiation ofNaegleria

The rapidity of the optional 90-min differentiation ofNaegleria gruberifrom amoebae to flagellates suggests the possibility of a free-running cascade of events from initiating stimulus through gene expression to organelle assembly and cell morphogenesis. Instead our experiments reveal two points early in the differentiation at which the strength of the inducing stimulus is reevaluated by the cells. Two new physical start signals for differentiation, temperature downshift (ΔT) and mechanical agitation, are shown to regulate differentiation synergistically with each other and with previously defined signals. A ΔTof −10°C induces complete differentiation directly in the growth environment, whereas smaller ΔTs initiate differentiation and allow it to progress for a short time, after which the cells “hold” for up to 4 h, awaiting a stimulus to continue differentiation. Our work defines two “holdpoints,” optional points in development where progress can stop, awaiting a suitable signal, while cells retain whatever intermediates represent progress. We propose that such holdpoints, which can be detected in this system because of the temporal reproducibility of the differentiation, are likely to be found in other differentiating cells.     

An OR logic gate based on two molecular beacons

Design of elementary molecular logic gates is the key and the fundamental of performing complicated Boolean calculations. Herein, we report a strategy for constructing a DNA-based OR gate by using the mechanism of sequence recognition and the principle of fluorescence resonance energy transfer (FRET). In this system, the gate is entirely composed of a single strand of DNA (A, B and C) and the inputs are the molecular beacon probes (MB1 and MB2). Changes in fluorescence intensity confirm the realization of the OR logic operation and electrophoresis experiments verify these results. Our successful application of DNA to perform the binary operation represents that DNA can serve as an efficient biomaterial for designing molecular logic gates and devices.     

Rapid detection of deletions in the Duchenne muscular dystrophy gene by PCR amplification of deletion-prone exon sequences

Summary Using the polymerase chain reaction (PCR) technique, we have screened the DNA of 42 patients with Duchenne or Becker muscular dystrophy for deletions within the DMD gene. Two regions within putative deletion hot spots of this gene were tested, and deletions were found in 16.6% of patients. The oligonucleotide primers employed in this study initiate the amplification of exon sequences and were used to test the suitability and reliability of PCR in deletion screening and prenatal diagnosis using various numbers of cycles and artificial contamination ratios. We compared our approach with both multiplex DNA amplification and Southern blot analysis. A comparative evaluation of currently available techniques is presented.     

Development of a URA5 integrative cassette for gene disruption in the Candida guilliermondii ATCC 6260 strain

We designed an efficient transformation system for Candida guilliermondii based on a ura5 ATCC 6260 derived recipient strain and a URA5 recyclable selection marker. This “URA5 blaster” disruption system represents a powerful tool to study the function of a large pallet of genes in this yeast of clinical and biotechnological interest.     

“Turn off–on” phosphorescent biosensors for detection of DNA based on quantum dots/acridine orange

A “turn off–on” switch mode was established by using the interaction between acridine orange (AO) and DNA as an input signal and using the room temperature phosphorescence (RTP) reversible change of 3-mercaptopropionic acid (MPA)-capped Mn-doped ZnS quantum dots (QDs) as an output signal in biological fluids. AO was absorbed into the surface of Mn-doped ZnS QDs via electrostatic attraction and, thus, formed a ground-state complex through photoinduced electron transfer (PIET). This complex quenched the phosphorescence of Mn-doped ZnS QDs and then rendered the system into the “turn-off” mode. Along with the addition of DNA and embedded binding with DNA, AO was competitively induced to fall off from the surface of Mn-doped ZnS QDs and embed into the double helix structure of DNA. As a result, the RTP of Mn-doped ZnS QDs was recovered and the system consequently was rendered into “turn-on” mode. In this case, a new biosensor for DNA detection was built and has a detection limit of 0.033 mg L⁻¹ and a detection range from 0.033 to 20 mg L⁻¹. What is more, this kind of biosensor does not require complex pretreatments and is free from the interference from autofluorescence and scattering light. Thus, this biosensor can be used to detect DNA in biological fluids.