A lead-dependent DNAzyme with a two-step mechanism

A detailed biochemical and mechanistic study of in vitro selected variants of 8-17 DNAzymes is presented. Even though the 8-17 DNAzyme motif has been obtained through in vitro selection under three different conditions involving 10 mM Mg(2+) (called 8-17), 0.5 mM Mg(2+)/50 mM histidine (called Mg5), or 100 microM Zn(2+) (called 17E), all variants are shown to be the most active with Pb(2+) (8-17: k(obs) approximately 0.5 min(-1); Mg5: k(obs) approximately 2 min(-1); 17E: k(obs) approximately 1 min(-1) with 200 microM Pb(2+) at pH 5.0). For the 17E variant of the 8-17 DNAzyme, the single-turnover rate constants followed the order of Pb(2+) > Zn(2+) > Mn(2+) approximately Co(2+) > Ni(2+) > Mg(2+) approximately Ca(2+) > Sr(2+) approximately Ba(2+). The catalytic rate is half-maximal at 13.5 microM Pb(2+), 0.97 mM Zn(2+), or 10.5 mM Mg(2+), suggesting that the metal-binding affinity of the DNAzymes is in the order of Pb(2+) > Zn(2+) > Mg(2+). The Pb(2+)-dependent activity increases linearly with pH and the slope of the plot of log k(obs) versus pH is approximately 1, suggesting a single deprotonation in the rate-limiting step of the reaction. Sequence variations of the DNAzyme confirm the importance of the G*T wobble pair, the two loops and the intervening stem in maintaining the active conformation of the system. While Mg(2+) and Zn(2+) catalyze only a transesterification reaction with formation of a product containing a 2',3'-cyclic phosphate, Pb(2+) catalyzes a transesterification reaction followed by hydrolysis of the 2',3'-cyclic phosphate. Although this two-step mechanism has shown to be operative in protein ribonucleases and in the leadzyme RNAzyme, it is now demonstrated for the first time that this DNAzyme may also use the same mechanism. Therefore, the two-step mechanism is observed in metalloenzymes of all classes, and this 8-17 DNAzyme provides a simple, stable, and cost-effective model system for understanding the structure of Pb(2+)-binding sites and their roles in the two-step mechanism.     

Introduction of guanidinium-modified deoxyuridine into the substrate binding regions of DNAzyme 10–23 to enhance target affinity: Implications for DNAzyme design

Deoxyribozymes (DNAzymes) are important catalysts for potential therapeutic RNA destruction and no DNAzyme has received as much notoriety in terms of therapeutic use as the Mg²⁺-dependent RNA-cleaving DNAzyme 10–23 (Dz10–23). As such, we have investigated the synthetic modification of Dz10–23 with a guanidinium group, a functionality that reduces the anionic nature and can potentially enhance the membrane permeability of oligonucleotides. To accomplish this, we synthesized a heretofore unknown phosphoramidite, 5-(N,N′-biscyanoethoxycarbonyl)-guanidinoallyl-2′-deoxyuridine and then incorporated it into oligonucleotides via solid phase synthesis to study duplex stability and its effect on Dz10–23. This particular modification was chosen as it had been used in the selection of Mg²⁺-free self-cleaving DNAzymes; as such this will enable the eventual comparison of modified DNAzymes that do or do not depend on Mg²⁺ for catalysis. Consistent with antecedent studies that have incorporated guanidinium groups into DNA oligonucleotides, this guanidinium-modified deoxyuridine enhanced the thermal stability of resulting duplexes. Surprisingly however, Dz10–23, when synthesized with modified residues in the substrate binding regions, was found to be somewhat less active than its non-modified counterpart. This work suggests that this particular system exhibits uniform binding with respect to ground state and transition state and provides insight into the challenge of re-engineering a Mg²⁺-dependent DNAzyme with enhanced catalytic activity.     

Sensitive dual DNAzymes-based sensors designed by grafting self-blocked G-quadruplex DNAzymes to the substrates of metal ion-triggered DNA/RNA-cleaving DNAzymes

A universal label-free metal ion sensor design strategy was developed on the basis of a metal ion-specific DNA/RNA-cleaving DNAzyme and a G-quadruplex DNAzyme. In this strategy, the substrate strand of the DNA/RNA-cleaving DNAzyme was designed as an intramolecular stem-loop structure, and a G-rich sequence was caged in the double-stranded stem and could not form catalytically active G-quadruplex DNAzyme. The metal ion-triggered cleavage of the substrate strand could result in the release of the G-rich sequence and subsequent formation of a catalytic G-quadruplex DNAzyme. The self-blocking mechanism of the G-quadruplex DNAzyme provided the sensing system with a low background signal. The signal amplifications of both the DNA/RNA-cleaving DNAzyme and the G-quadruplex DNAzyme provided the sensing system with a high level of sensitivity. This sensor design strategy can be used for metal ions with reported specific DNA/RNA-cleaving DNAzymes and extended for metal ions with unique properties. As examples, dual DNAzymes-based Cu(2+), Pb(2+) and Hg(2+) sensors were designed. These "turn-on" colorimetric sensors can simply detect Cu(2+), Pb(2+) and Hg(2+) with high levels of sensitivity and selectivity, with detection limits of 4nM, 14nM and 4nM, respectively.     

Influence of conformationally restricted pyrimidines on the activity of 10-23 DNAzymes

The catalytic core of a 10-23 DNAzyme was modified introducing conformationally restricted nucleosides such as (2'R)-, (2'S)-2'-deoxy-2'-C-methyluridine, (2'R)-, (2'S)-2'-deoxy-2'-C-methylcytidine, 2,2'-anhydrouridine and LNA-C, in one, two or three positions. Catalytic activities under pseudo first order conditions were compared at different Mg(2+) concentrations using a short RNA substrate. At low Mg(2+) concentrations, triple modified DNAzymes with similar kinetic performance to that displayed by the non-modified control were identified. In the search for a partial explanation of the obtained results, in silico studies were carried out in order to explore the conformational behavior of 2'-deoxy-2'-C-methylpyrimidines in the context of a loop structure, suggesting that at least partial flexibility is needed for the maintenance of activity. Finally, the modified 2'-C-methyl DNAzyme activity was tested assessing the inhibition of Stat3 expression and the decrease in cell proliferation using the human breast cancer cell line T47D.     

A general strategy for effector-mediated control of RNA-cleaving ribozymes and DNA enzymes

A novel and general approach is described for generating versions of RNA-cleaving ribozymes (RNA enzymes) and DNAzymes (DNA enzymes), whose catalytic activity can be controlled by the binding of activator molecules. Variants of the RNA-cleaving 10-23 DNAzyme and 8-17 DNAzyme were created, whose catalysis was activated by up to approximately 35-fold by the binding of the effector adenosine. The design of such variants was possible even though the tertiary folding of the two DNAzymes is not known. Variants of the hammerhead ribozyme were constructed, to respond to the effectors ATP and flavin mononucleotide. Whereas in conventional allosteric ribozymes, effector-binding modulates the chemical step of catalysis, here, effectors exercise their effect upon the substrate-binding step, by stabilizing the enzyme-substrate complex. Because such an approach for controlling the activity of DNAzymes/ribozymes requires no prior knowledge of the enzyme's secondary or tertiary folding, this regulatory strategy should be generally applicable to any RNA-cleaving ribozyme or DNAzyme, natural or in vitro selected, provided substrate-recognition is achieved by Watson-Crick base-pairing.     

c-Jun Is critical for the progression of osteosarcoma: proof in an orthotopic spontaneously metastasizing model

The oncogene c-Jun has been found to be up-regulated in a variety of cancers including osteosarcoma. DNA enzymes (DNAzymes) are oligonucleotides capable of specific catalysis of target mRNA. A c-Jun DNAzyme inhibited the growth and metastasis of osteosarcoma in an orthotopic spontaneously metastasizing model of the disease. c-Jun down-regulation-mediated apoptosis in osteosarcoma cells involved caspase-1, caspase-2, and caspase-8, but not the Fas/FasL pathway. Clinically, knockdown of c-Jun with DNAzymes may proffer an improved treatment outcome for these tumors originating in bone.     

An Efficient Catalytic DNA that Cleaves L-RNA

Many DNAzymes have been isolated from synthetic DNA pools to cleave natural RNA (D-RNA) substrates and some have been utilized for the design of aptazyme biosensors for bioanalytical applications. Even though these biosensors perform well in simple sample matrices, they do not function effectively in complex biological samples due to ubiquitous RNases that can efficiently cleave D-RNA substrates. To overcome this issue, we set out to develop DNAzymes that cleave L-RNA, the enantiomer of D-RNA, which is known to be completely resistant to RNases. Through in vitro selection we isolated three L-RNA-cleaving DNAzymes from a random-sequence DNA pool. The most active DNAzyme exhibits a catalytic rate constant ~3 min^-1 and has a structure that contains a kissing loop, a structural motif that has never been observed with D-RNA-cleaving DNAzymes. Furthermore we have used this DNAzyme and a well-known ATP-binding DNA aptamer to construct an aptazyme sensor and demonstrated that this biosensor can achieve ATP detection in biological samples that contain RNases. The current work lays the foundation for exploring RNA-cleaving DNAzymes for engineering biosensors that are compatible with complex biological samples.     

Cellular uptake,distribution, and stability of 10-23 deoxyribozymes

The cellular uptake, intracellular distribution, and stability of 33-mer deoxyribozyme oligonucleotides (DNAzymes) were examined in several cell lines. PAGE analysis revealed that there was a weak association between the DNAzyme and DOTAP or Superfect transfection reagents at charge ratios that were minimally toxic to cultured cells. Cellular uptake was analyzed by cell fractionation of radiolabeled DNAzyme, by FACS, and by fluorescent microscopic analysis of FITC-labeled and TAMRA-labeled DNAzyme. Altering DNAzyme size and chemistry did not significantly affect uptake into cells. Inspection of paraformaldehyde-fixed cells by fluorescence microscopy revealed that DNAzyme was distributed primarily in punctate structures surrounding the nucleus and that substantial delivery to the nucleus was not observed up to 24 hours after initiation of transfection. Incubation in human serum or plasma demonstrated that a 3'-inversion modification greatly increased DNAzyme stability (t(1/2) approximately 22 hours) in comparison to the unmodified form (t(1/2) approximately 70 minute). The 3'-inversion-modified DNAzymes remained stable during cellular uptake, and catalytically active oligonucleotide could be extracted from the cells 24 hours posttransfection. In smooth muscle cell proliferation assay, the modified DNAzyme targeting the c-myc gene showed a much stronger inhibitory effect than did the unmodified version. The present study demonstrates that DNAzymes with a 3'-inversion are readily delivered into cultured cells and are functionally stable for several hours in serum and within cells.     

A High-Throughput Kinetic Assay for RNA-Cleaving Deoxyribozymes

Determining kinetic constants is important in the field of RNA-cleaving deoxyribozymes (DNAzymes). Using todays conventional gel assays for DNAzyme assays is time-consuming and laborious. There have been previous attempts at producing new and improved assays; however these have drawbacks such as incompatibility with structured DNAzymes, enzyme or substrate modifications and increased cost. Here we present a new method for determining single-turnover kinetics of RNA-cleaving DNAzymes in real-time and in a high-throughput fashion. The assay is based on an intercalating fluorescent dye, PicoGreen, with high specificity for double-stranded DNA and heteroduplex DNA-RNA in this case formed between the DNAzyme and the target RNA. The fluorescence decreases as substrate is converted to product and is released from the enzyme. Using a Flexstation II multimode plate reader with built in liquid handling we could automate parts of the assay. This assay gives the possibility to determine single-turnover kinetics for up to 48 DNAzymes simultaneously. As the fluorescent probe is extrinsic there is no need for enzyme or substrate modifications, making this method less costly compared to other methods. The main novelty of this assay is the possibility of using full-length mRNA as the DNAzyme target.     

DNAzyme-mediated catalysis with only guanosine and cytidine nucleotides

Single-stranded DNA molecules have the capacity to adopt catalytically active structures known as DNAzymes, although the fundamental limits of this ability have not been determined. Starting with a parent DNAzyme composed of all four types of standard nucleotides, we conducted a search of the surrounding sequence space to identify functional derivatives with catalytic cores composed of only three, and subsequently only two types of nucleotides. We provide the first report of a DNAzyme that contains only guanosine and cytidine deoxyribonucleotides in its catalytic domain, which consists of just 13 nucleotides. This DNAzyme catalyzes the Mn²⁺-dependent cleavage of an RNA phosphodiester bond ~5300-fold faster than the corresponding uncatalyzed reaction, but ~10 000-fold slower than the parent. The demonstration of a catalytic DNA molecule made from a binary nucleotide alphabet broadens our understanding of the fundamental limits of nucleic-acid-mediated catalysis.     

Characterization of non-8-17 sequences uncovers structurally diverse RNA-cleaving deoxyribozymes

RNA-cleaving deoxyribozymes (DNAzymes) can be isolated from random-sequence DNA pools via the process of in vitro selection. However, small and simple catalytic motifs, such as the 8-17 DNAzyme, are commonly observed in sequence space, presenting a challenge in discovering large and complex DNAzymes. In an effort to investigate underrepresented molecular species derived from in vitro selection, in this study we sought to characterize non-8-17 sequences obtained from a previous in vitro selection experiment wherein the 8-17 deoxyribozyme was the dominant motif. We examined 9 sequence families from 21 motifs by characterizing their structural and functional features. We discovered 9 novel deoxyribozyme classes with large catalytic domains (>40 nucleotides) utilizing three-way or four-way junction structural frameworks. Kinetic studies revealed that these deoxyribozymes exhibit moderate to excellent catalytic rates (k(obs) from 0.003 to 1 min(-1)), compared to other known RNA-cleaving DNAzymes. Although chemical probing experiments, site-directed mutational analyses, and metal cofactor dependency tests suggest unique catalytic cores for each deoxyribozyme, common dinucleotide junction selectivity was observed between DNAzymes with similar secondary structural features. Together, our findings indicate that larger, structurally more complex, and diverse catalytic motifs are able to survive the process of in vitro selection despite a sequence space dominated by smaller and structurally simpler catalysts.     

Coarse-Grained Brownian Dynamics Simulations of the 10-23 DNAzyme

Deoxyribozymes (DNAzymes) are single-stranded DNA that catalyze nucleic acid biochemistry. Although a number of DNAzymes have been discovered by in vitro selection, the relationship between their tertiary structure and function remains unknown. We focus here on the well-studied 10-23 DNAzyme, which cleaves mRNA with a catalytic efficiency approaching that of RNase A. Using coarse-grained Brownian dynamics simulations, we find that the DNAzyme bends its substrate away from the cleavage point, exposing the reactive site and buckling the DNAzyme catalytic core. This hypothesized transition state provides microscopic insights into experimental observations concerning the size of the DNAzyme/substrate complex, the impact of the recognition arm length, and the sensitivity of the enzymatic activity to point mutations of the catalytic core. Upon cleaving the pertinent backbone bond in the substrate, we find that the catalytic core of the DNAzyme unwinds and the overall complex rapidly extends, in agreement with experiments on the related 8-17 DNAzyme. The results presented here provide a starting point for interpreting experimental data on DNAzyme kinetics, as well as developing more detailed simulation models. The results also demonstrate the limitations of using a simple physical model to understand the role of point mutations.     

A heme•DNAzyme activated by hydrogen peroxide catalytically oxidizes thioethers by direct oxygen atom transfer rather than by a Compound I-like intermediate

Hemin [Fe(III)-protoporphyrin IX] is known to bind tightly to single-stranded DNA and RNA molecules that fold into G-quadruplexes (GQ). Such complexes are strongly activated for oxidative catalysis. These heme•DNAzymes and ribozymes have found broad utility in bioanalytical and medicinal chemistry and have also been shown to occur within living cells. However, how a GQ is able to activate hemin is poorly understood. Herein, we report fast kinetic measurements (using stopped-flow UV–vis spectrophotometry) to identify the H₂O₂-generated activated heme species within a heme•DNAzyme that is active for the oxidation of a thioether substrate, dibenzothiophene (DBT). Singular value decomposition and global fitting analysis was used to analyze the kinetic data, with the results being consistent with the heme•DNAzyme''s DBT oxidation being catalyzed by the initial Fe(III)heme–H₂O₂ complex. Such a complex has been predicted computationally to be a powerful oxidant for thioether substrates. In the heme•DNAzyme, the DNA GQ enhances both the kinetics of formation of the active intermediate as well as the oxidation step of DBT by the active intermediate. We show, using both stopped flow spectrophotometry and EPR measurements, that a classic Compound I is not observable during the catalytic cycle for thioether sulfoxidation.     

A self-cleaving DNA enzyme modified with amines, guanidines and imidazoles operates independently of divalent metal cations (M2+)

The selection of modified DNAzymes represents an important endeavor in expanding the chemical and catalytic properties of catalytic nucleic acids. Few examples of such exist and to date, there is no example where three different modified bases have been simultaneously incorporated for catalytic activity. Herein, dCTP, dATP and dUTP bearing, respectively, a cationic amine, an imidazole and a cationic guanidine, were enzymatically polymerized on a DNA template for the selection of a highly functionalized DNAzyme, called DNAzyme 9-86, that catalyzed (M²⁺)-independent self-cleavage under physiological conditions at a single ribo(cytosine)phosphodiester linkage with a rate constant of (0.134 ± 0.026) min⁻¹. A pH rate profile analysis revealed pK_a's of 7.4 and 8.1, consistent with both general acid and base catalysis. The presence of guanidinium cations permits cleavage at significantly higher temperatures than previously observed for DNAzymes with only amines and imidazoles. Qualitatively, DNAzyme 9-86 presents an unprecedented ensemble of synthetic functionalities while quantitatively it expresses one of the highest reported values for any self-cleaving nucleic acid when investigated under M²⁺-free conditions at 37°C.     

DNAzyme-based highly sensitive electronic detection of lead via quantum dot-assembled amplification labels

An electronic DNAzyme sensor for highly sensitive detection of Pb(2+) is demonstrated by coupling the significant signal enhancement of the layer-by-layer (LBL) assembled quantum dots (QDs) with Pb(2+) specific DNAzymes. The presence of Pb(2+) cleaves the DNAzymes and releases the biotin-modified fragments, which further hybridize with the complementary strands immobilized on the gold substrate. The streptavidin-coated, QD LBL assembled nanocomposites were captured on the gold substrate through biotin-streptavidin interactions. Subsequent electrochemical signals of the captured QDs upon acid dissolution provide quantitative information on the concentrations of Pb(2+) with a dynamic range from 1 to 1000 nM. Due to the dramatic signal amplification by the numerous QDs, subnanomolar level (0.6 nM) of Pb(2+) can be detected. The proposed sensor also shows good selectivity against other divalent metal ions and thus holds great potential for the construction of general DNAzyme-based sensing platform for the monitoring of other heavy metal ions.     

Dissecting metal ion-dependent folding and catalysis of a single DNAzyme

Protein metalloenzymes use various modes for functions for which metal-dependent global conformational change is required in some cases but not in others. In contrast, most ribozymes require a global folding that almost always precedes enzyme reactions. Herein we studied metal-dependent folding and cleavage activity of the 8-17 DNAzyme using single-molecule fluorescence resonance energy transfer. Addition of Zn2+ and Mg2+ induced folding of the DNAzyme into a more compact structure followed by a cleavage reaction, which suggests that the DNAzyme may require metal-dependent global folding for activation. In the presence of Pb2+, however, the cleavage reaction occurred without a precedent folding step, which suggests that the DNAzyme may be prearranged to accept Pb2+ for the activity. Neither ligation reaction of the cleaved substrates nor dynamic changes between folded and unfolded states was observed. These features may contribute to the unusually fast Pb2+-dependent reaction of the DNAzyme. These results suggest that DNAzymes can use all modes of activation that metalloproteins use.     

Positively charged side chains in protein farnesyltransferase enhance catalysis by stabilizing the formation of the diphosphate leaving group

Protein farnesyltransferase (FTase) requires both Zn(2+) and Mg(2+) for efficient catalysis of the formation of a thioether bond between carbon-1 of farnesyldiphosphate (FPP) and the cysteine thiolate contained in the carboxy-terminal CaaX sequence of target proteins. Millimolar concentrations of Mg(2+) accelerate catalysis by as much as 700-fold in FTase. Although FTase lacks a typical DDXXD Mg(2+) binding site found in other enzymes that use Mg(2+) for diphosphate stabilization, D352beta in FTase has been implicated in binding Mg(2+) (Pickett et al. (2003) J. Biol. Chem. 278, 51243). Structural studies demonstrate that the diphosphate (PPi) group of FPP resides in a binding pocket made up of highly positively charged side chains, including residues R291beta and K294beta, prior to formation of an active conformation. Analysis of the Mg(2+) dependence of FTase mutants demonstrates that these positively charged residues decrease the Mg(2+) affinity up to 40-fold. In addition, these residues enhance the farnesylation rate constant by almost 80-fold in the presence of Mg(2+), indicating that these residues are not simply displaced by Mg(2+) during the reaction. Mutations at R291beta increase the pK(a) observed in the magnesium affinity, suggesting that this arginine stabilizes the deprotonated form of the PPi leaving group. Furthermore, binding and catalysis data using farnesylmonophosphate (FMP) as a substrate indicate that the side chains of R291beta and K294beta interact mainly with the beta-phosphate of FPP during the chemical reaction. These results allow refinement of the model of the Mg(2+) binding site and demonstrate that positive charge stabilizes the developing charge on the diphosphate leaving group.     

Mechanistic characterization of the HDV genomic ribozyme: assessing the catalytic and structural contributions of divalent metal ions within a multichannel reaction mechanism

Hepatitis delta virus (HDV) uses genomic and antigenomic ribozymes in its replication cycle. We examined ribozyme self-cleavage over eight orders of magnitude of Mg(2+) concentration, from approximately 10(-9) to 10(-1) M. These experiments were carried out in 1 M NaCl to aid folding of the ribozyme and to control the ionic strength. The concentration of free Mg(2+) ions was established using an EDTA-Mg(2+) buffered system. Over the pH range of 5-9, the rate was independent of Mg(2+) concentration up to 10(-7) M, and of the addition of a large excess of EDTA. This suggests that in the presence of 1 M NaCl, the ribozyme can fold and cleave without using divalent metal ions. Br?nsted analysis under these reaction conditions suggests that solvent and hydroxide ions may play important roles as general base and specific base catalysts. The observed rate constant displayed a log-linear dependence on intermediate Mg(2+) concentration from approximately 10(-7) to 10(-4) M. These data combined with the shape of the pH profile under these conditions are consistent with the binding of at least one structural divalent metal ion that does not participate in catalysis and binds tighter at lower pH. No evidence for a catalytic role for Mg(2+) was found at low or intermediate Mg(2+) concentrations. Addition of Mg(2+) to physiological and higher concentrations, from 10(-3) to 10(-1) M, revealed a second saturable divalent metal ion which binds tighter at high pH. The shape of the pH profile is inverted relative to that at low Mg(2+) concentrations, consistent with a general acid-base catalysis mechanism in which a cytosine (C75) acts as the general acid and a hydroxide ion from the divalent metal ion, or possibly from solvent, acts as the base. Overall, the data support a model in which the HDV ribozyme can self-cleave by multiple divalent ion-independent and -dependent channels, and in which the contribution of Mg(2+) to catalysis is modest at approximately 25-fold. Surface electrostatic potential maps were calculated on the self-cleaved form of the ribozyme using the nonlinear Poisson-Boltzmann equation. These calculations revealed several patches of high negative potential, one of which is present in a cleft near N4 of C75. These calculations suggest that distinct catalytic and structural metal ion sites exist on the ribozyme, and that the negative potential at the active site may help shift the pK(a) for N3 of C75 toward neutrality.     

Single-stranded DNAzyme-based Pb2+ fluorescent sensor that can work well over a wide temperature range

DNAzymes have become an excellent choice for sensing applications. Based on DNAzymes, three generations of Pb(2+) fluorescent sensors have been reported. In these sensors, two oligonucleotide strands (substrate strand and enzyme strand) were used, which not only increased the complexity of the detection system, but also brought some difficulties for the use of the sensors at elevated temperatures. To overcome this problem, a single-stranded DNAzyme-based Pb(2+) fluorescent sensor was designed by combining the substrate sequence and the enzyme sequence into one oligonucleotide strand. The intramolecular duplex structure of this single-stranded DNAzyme kept the fluorophore and the quencher, labeled at its two ends, in close proximity; thus the background fluorescence was significantly suppressed. Using this fluorescent sensor, Pb(2+) quantitation can be achieved with high sensitivity and high selectivity. In addition, the extraordinary stability of the intramolecular duplex structure could assure a low background fluorescence at high temperature, even if the number of complementary base pairs between the substrate sequence and the enzyme sequence was reduced, allowing the sensor to work well over a wide temperature range. Similar performances of the fluorescent sensor at 4, 25 and 37°C suggested that this sensor has a good ability to resist temperature fluctuations.