Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:3.1.26.4 (
RNase H
)
2,751
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
ribonuclease H
(
RNH
) activity of HIV-1 reverse transcriptase (RT) is essential for viral replication and can be a target for drug development. Yet, no
RNH
inhibitor to date has substantial antiviral activity to allow advancement into clinical development. Herein, we describe our characterization of the detailed binding mechanisms of
RNH
active-site inhibitors, YLC2-155 and ZW566, that bind to the
RNH
domain through divalent metal ions, using
NMR
, molecular docking, and quantum mechanical calculations. In the presence of Mg
2+
,
NMR
spectra of
RNH
exhibited split (two) resonances for some residues upon inhibitor binding, suggesting two binding modes, an observation consistent with the docking results. The relative populations of the two binding conformers were independent of inhibitor or Mg
2+
concentration, with one conformation consistently more favored. In our docking study, one distinctive pose of ZW566 showed more interactions with surrounding residues of
RNH
compared to the analogous binding pose of YLC2-155. Inhibitor titration experiments revealed a lower dissociation constant for ZW566 compared to YLC2-155, in agreement with its higher inhibitory activity. Mg
2+
titration data also indicated a stronger dependence on Mg
2+
for the
RNH
interaction with ZW566 compared to YLC2-155. Combined docking and quantum mechanical calculation results suggest that stronger metal coordination as well as more protein-inhibitor interactions may account for the higher binding affinity of ZW566. These findings support the idea that strategies for the development of potent competitive active site
RNH
inhibitors should take into account not only metal-inhibitor coordination but also protein-inhibitor interaction and conformational selectivity.
...
PMID:Determinants of Active-Site Inhibitor Interaction with HIV-1 RNase H. 3157 24
Sequence-specific
protein-based
ribonucleases are not found in nature. Absolute sequence selectivity in RNA cleavage
in vivo
normally requires multi-component complexes that recruit a guide RNA or DNA for target recognition and a protein-RNA assembly for catalytic functioning (e.g. RNAi molecular machinery,
RNase H
). Recently discovered peptidyl-oligonucleotide synthetic ribonucleases selectively knock down pathogenic RNAs by irreversible cleavage to offer unprecedented opportunities for control of disease-relevant RNA. Understanding how to increase their potency, selectivity and catalytic turnover will open the translational pathway to successful therapeutics. Yet, very little is known about how these chemical ribonucleases bind, cleave and leave their target. Rational design awaits this understanding in order to control therapy, particularly how to overcome the trade-off between sequence specificity and potency through catalytic turnover. We illuminate this here by characterizing the interactions of these chemical RNases with both complementary and non-complementary RNAs using T
m
profiles, fluorescence, UV-visible and
NMR
spectroscopies. Crucially, the level of counter cations, which are tightly-controlled within cellular compartments, also controlled these interactions. The oligonucleotide component dominated interaction between conjugates and
complementary
targets in the presence of physiological levels of counter cations (K
+
), sufficient to prevent repulsion between the complementary nucleic acid strands to allow Watson-Crick hydrogen bonding. In contrast, the positively-charged catalytic peptide interacted poorly with target RNA, when counter cations similarly screened the negatively-charged sugar-phosphate RNA backbones. The peptide only became the key player, when counter cations were insufficient for charge screening; moreover, only under such non-physiological conditions did conjugates form strong complexes with
non-complementary
RNAs.Communicated by Ramaswamy H. Sarma.
...
PMID:RNA knockdown by synthetic peptidyl-oligonucleotide ribonucleases: behavior of recognition and cleavage elements under physiological conditions. 3224 55
ConspectusRNA-based technologies to control gene expression, such as RNA interference (RNAi) and CRISPR-Cas9, have become powerful tools in molecular biology and genomics. The exciting potential that RNAi and CRISPR-Cas9 may also become new therapeutic approaches has reinvigorated interest in chemically modifying RNA to improve its properties for in vivo applications. Chemical modifications can improve enzymatic stability, in vivo delivery, cellular uptake, and sequence specificity as well as minimize off-target activity of short interfering RNAs (siRNAs) and CRISPR associated RNAs. While numerous good solutions for improving stability toward enzymatic degradation have emerged, optimization of the latter functional properties remains challenging. In this Account, we discuss synthesis, structure, and biological activity of novel nonionic analogues of RNA that have the phosphodiester backbone replaced by amide linkages (AM1). Our long-term goal is to use the amide backbone to improve the stability and specificity of siRNAs and other functional RNAs. Our work in this area was motivated by early discoveries that nonionic backbone modifications, including AM1, did not disturb the overall structure or thermal stability of RNA duplexes. We hypothesized that the reduced negative charge and hydrophobic nature of the AM1 backbone modification might be useful in optimizing functional applications through enhanced cellular uptake, and might suppress unwanted off-target effects of siRNAs.
NMR
and X-ray crystallography studies showed that AM1 was an excellent mimic of phosphodiester linkages in RNA. The local conformational changes caused by the amide linkages were easily accommodated by small adjustments in RNA's conformation. Further, the amide carbonyl group assumed an orientation that is similar to one of the nonbridging P-O bonds, which may enable amide/phosphate mimicry by conserving hydrogen bonding interactions. The crystal structure of a short amide-modified DNA-RNA hybrid in complex with
RNase H
indicated that the amide N-H could also act as an H-bond donor to stabilize RNA-protein interactions, which is an interaction mode not available to phosphate groups. Functional assays established that amides were well tolerated at internal positions in both strands of siRNAs. Surprisingly, amide modifications in the middle of the guide strand and at the 5'-end of the passenger strand increased RNAi activity compared to unmodified siRNA. Most importantly, an amide linkage between the first and second nucleosides of the passenger strand completely abolished its undesired off-target activity while enhancing the desired RNAi activity. These results suggest that RNAi may tolerate more substantial modifications of siRNAs than the chemistries tried so far. The findings are also important and timely because they demonstrate that amide modifications may reduce off-target activity of siRNAs, which remains an important roadblock for clinical use of RNAi. Taken together, our work suggests that amide linkages have underappreciated potential to optimize the biological and pharmacological properties of RNA. Expanded use of amide linkages in RNA to enhance CRISPR and other technologies requiring chemically stable, functional mimics of noncoding RNAs is expected.
...
PMID:Amide-Modified RNA: Using Protein Backbone to Modulate Function of Short Interfering RNAs. 3265 52
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