Equivalence of the Transition Heat Capacities of Proteins and DNA

It has been reported for many globular proteins that the native heat capacity at 25°C, per gram, is the same. This has been interpreted to indicate that heat capacity is a fundamental property of native proteins that provides important information on molecular structure and stability. Heat capacities for both proteins and DNA has been suggested to be related to universal effects of hydration/solvation on native structures. Here we report on results from thermal denaturation analysis of two well-known proteins, human serum albumin and lysozyme, and a short DNA hairpin. The transition heat capacities at the Tm for the three molecules were quantitatively evaluated by differential scanning calorimetry. When normalized per gram rather than per mol the transition heat capacities were found to be precisely equivalent. This observation for the transition heat capacities of the proteins is consistent with previous reports. However, an identical transition heat capacity for DNA has not been reported and was unexpected. Further analysis of the collected data suggested a mass dependence of hydration effects on thermal denaturation that is preserved at the individual protein amino acid and DNA base levels. Equivalence of transition heat capacities suggests the possibility of a universal role of hydration effects on the thermal stability of both proteins and DNA.

Quantum Surprises from the Watson-Crick and Hoogsteen G·C Nucleobase Pairs: A Comprehensive QM/QTAIM Investigation

In this study at the MP2/6-311++G(d,p)//B3LYP/6-311++G(d,p) level of theory in the isolated state it was revealed 14 novel physico-chemical mechanisms of the tautomerization of the G·C nucleotide base pairs in the Watson-Crick G·C(WC) / G*·C*(WC), reverse Watson-Crick G*·C*(rWC) / G·C*O2(rWC), Hoogsteen G*t·C*(H) / G*N7·C(H) or reverse Hoogsteen G*t·C*(rH) / G*tN7·C(rH) configurations into the wobble (wWC, wH) and reverse wobble (rwWC, rwН) base pairs: 1. G·C(WC)↔G·C*(rwWC), 2./3. G*·C*(WC)↔G·C*(rwWC)/G*N2·C*(rwWC), 4. G*·C*(rWC)↔G*·C(wWC), 5. G·C*O2(rWC)↔G·C*(wWC); 6./7./8./9. G*t·C*(H)↔G*t·C(rwН)/G*t·C*O2(wH)/G*t·C*O2(rwН)/G*tN7·C*(rwН)↔G*t·C*O2(rwН), 10. G*N7·C(H)↔G*t·C(wH) amino, 11./12. G*t·C*(rH)↔G*N7·C*(wН)/G*t·C(wН), 13. G*tN7·C(rH)↔G*tN7·C*(wН)↔G*t·C(wН) and 14. G*N7·C*(rwH)↔G*N7·C*(rwH) perp↔G-·C+(wH)↔G*t·C(rwН) reaction pathways. It was established that the presence in the base pair of the two anti-parallel neighboring H-bonds is a necessary and sufficient condition for the implementation of such transformations, since it enables intermolecular proton transfer between the bases inside the base pair. It was found out that these tautomeric transitions are controlled by the TSs with quasi-orthogonal structure, which are tight G+·C-/G-·C+ ion pairs, joined by at least two parallel intermolecular H-bonds, connected on a common negatively charged endocyclic N-/C- atoms – proton acceptor. All reaction pathways have been reliably confirmed. These transitions are accompanied by the changing of the mutual cis-orientation of the N9H and N1H glycosidic bonds of the bases on the trans-orientation and vice versa. These data complement the reported earlier mechanisms of the tautomerisations of the classical A·T and G·C DNA base pairs. Experimental verification of the novel G·C nucleobase pairs is looking as an attractive task for the future research.

Synthetic evolution of herbicide resistance using a T7 RNAP-based random DNA base editor

Synthetic directed evolution via localized sequence diversification and the simultaneous application of selection pressure is a promising method for producing new, beneficial alleles that affect traits of interest in diverse species; however, this technique has rarely been applied in plants. Developing systems to induce localized sequence diversification at high efficiency will expand our ability to evolve traits of interest that improve global food security. In this study, we designed, built, and tested a chimeric fusion of T7 RNA Polymerase (RNAP) and deaminase to enable the localized sequence diversification of a target sequence of interest. We tested our T7 RNAP-DNA base editor in Nicotiana benthamiana transient assays to target a transgene expressing GFP under the control of the T7 promoter. More than 7% of C nucleotides were converted to T in long segments of the GFP sequence. We then targeted the T7 promoter-driven ACETOLACTATE SYNTHASE (ALS) sequence that had been stably integrated into the rice (Oryza sativa) genome and generated C-to-T and G-to-A transitions. We used herbicide treatment as a selection pressure for the evolution of the ALS sequence, resulting in the enrichment of herbicide-responsive residues. We then targeted these herbicide-responsive regions in the rice genome using a CRISPR-directed evolution platform and identified herbicide-resistant ALS variants. Thus, our system could be used for the continuous synthetic evolution of gene functions to produce variants with improved herbicide resistance, as well as for other trait engineering applications.

Mechanism of nucleotide discrimination by the translesion synthesis polymerase Rev1

Rev1 is a translesion DNA synthesis (TLS) polymerase involved in the bypass of adducted-guanine bases and abasic sites during DNA replication. During damage bypass, Rev1 utilizes a protein-template mechanism of DNA synthesis, where the templating DNA base is evicted from the Rev1 active site and replaced by an arginine side chain that preferentially binds incoming dCTP. Here, we utilize X-ray crystallography and molecular dynamics simulations to obtain structural insight into the dCTP specificity of Rev1. We show the Rev1 R324 protein-template forms sub-optimal hydrogen bonds with incoming dTTP, dGTP, and dATP that prevents Rev1 from adopting a catalytically competent conformation. Additionally, we show the Rev1 R324 protein-template forms optimal hydrogen bonds with incoming rCTP. However, the incoming rCTP adopts an altered sugar pucker, which prevents the formation of a catalytically competent Rev1 active site. This work provides novel insight into the mechanisms for nucleotide discrimination by the TLS polymerase Rev1.

NEIL1 and NEIL2 DNA glycosylases modulate anxiety and learning in a cooperative manner in mice

Oxidative DNA damage in the brain has been implicated in neurodegeneration and cognitive decline. DNA glycosylases initiate base excision repair (BER), the main pathway for oxidative DNA base lesion repair. NEIL1 and NEIL3 DNA glycosylases affect cognition in mice, while the role of NEIL2 remains unclear. Here, we investigate the impact of NEIL2 and its potential overlap with NEIL1 on behavior in knockout mouse models. Neil1−/−Neil2−/− mice display hyperactivity, reduced anxiety and improved learning. Hippocampal oxidative DNA base lesion levels are comparable between genotypes and no mutator phenotype is found. Thus, impaired canonical repair is not likely to explain the altered behavior. Electrophysiology suggests reduced axonal activation in the hippocampal CA1 region in Neil1−/−Neil2−/− mice and lack of NEIL1 and NEIL2 causes dysregulation of genes in CA1 relevant for synaptic function. We postulate a cooperative function of NEIL1 and NEIL2 in genome regulation, beyond canonical BER, modulating behavior in mice.

Impact of Oxidative DNA Damage and the Role of DNA Glycosylases in Neurological Dysfunction

The human brain requires a high rate of oxygen consumption to perform intense metabolic activities, accounting for 20% of total body oxygen consumption. This high oxygen uptake results in the generation of free radicals, including reactive oxygen species (ROS), which, at physiological levels, are beneficial to the proper functioning of fundamental cellular processes. At supraphysiological levels, however, ROS and associated lesions cause detrimental effects in brain cells, commonly observed in several neurodegenerative disorders. In this review, we focus on the impact of oxidative DNA base lesions and the role of DNA glycosylase enzymes repairing these lesions on brain function and disease. Furthermore, we discuss the role of DNA base oxidation as an epigenetic mechanism involved in brain diseases, as well as potential roles of DNA glycosylases in different epigenetic contexts. We provide a detailed overview of the impact of DNA glycosylases on brain metabolism, cognition, inflammation, tissue loss and regeneration, and age-related neurodegenerative diseases based on evidence collected from animal and human models lacking these enzymes, as well as post-mortem studies on patients with neurological disorders.

Processing of oxidatively damaged DNA dirty ends by APE1

Reactive oxygen species attack the structure of DNA, thus altering its base-pairing properties. Consequently, oxidative stress-associated DNA lesions are a major source of the mutation load that gives rise to cancer and other diseases. Base excision repair (BER) is the pathway primarily tasked with repairing DNA base damage, with apurinic/apyrimidinic endonuclease (APE1) having both APendonuclease and 3' to 5' exonuclease (exo) DNA cleavage functions. The lesion 8-oxo-7,8- dihydroguanine (8-oxoG) can enter the genome as either a product of direct damage to the DNA, or through polymerase insertion at the 3'-end of a DNA strand during replication or repair. Importantly, 3'-8-oxoG impairs the ligation step of BER and therefore must be removed by the exo activity of a surrogate enzyme to prevent double stranded breaks and cell death. In the present study, we characterize the exo activity of APE1 on 3'-8-oxoG substrates. These structures demonstrate that APE1 uses a unified mechanism for its exo activities that differs from its more canonical APendonuclease activity. In addition, through complementation of the structural data with enzyme kinetics and binding studies employing both wild-type and rationally designed APE1 mutants, we were able to identify and characterize unique protein:DNA contacts that specifically mediate 8-oxoG removal by APE1.