Linda S. Behlen scite author profile

Dicer processes long double-stranded RNA (dsRNA) and pre-microRNAs to generate the functional intermediates (short interfering RNAs and microRNAs) of the RNA interference pathway. Here we identify features of RNA structure that affect Dicer specificity and efficiency. The data presented show that various attributes of the 3 end structure, including overhang length and sequence composition, play a primary role in determining the position of Dicer cleavage in both dsRNA and unimolecular, short hairpin RNA (shRNA). We also demonstrate that siRNA end structure affects overall silencing functionality. Awareness of these new features of Dicer cleavage specificity as it is related to siRNA functionality provides a more detailed understanding of the RNAi mechanism and can shape the development of hairpins with enhanced functionality.

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Lead-catalyzed cleavage of yeast tRNAPhe mutants

Behlen¹,

Sampson²,

DiRenzo³

et al. 1990

Biochemistry

171

146

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Yeast tRNA(Phe) lacking modified nucleotides undergoes lead-catalyzed cleavage between nucleotides U17 and G18 at a rate very similar to that of its fully modified counterpart. The rates of cleavage for 28 tRNA(Phe) mutants were determined to define the structural requirements of this reaction. The cleavage rate was found to be very dependent on the identity and correct positioning of the two lead-coordinating pyrimidines defined by X-ray crystallography. Nucleotide changes that disrupted the tertiary interactions of tRNAPhe reduced the rate of cleavage even when they were distant from the lead binding pocket. However, nucleotide changes designed to maintain tertiary interactions showed normal rates of cleavage, thereby making the reaction of a useful probe for tRNA(Phe) structure. Certain mutants resulted in the enhancement of cleavage at a "cryptic" site at C48. The sequences of Escherichia coli tRNA(Phe) and yeast tRNA(Arg) were altered such that they acquired the ability to cleave at U17, confirming our understanding of the structural requirements for cleavage. This mutagenic analysis of the lead cleavage domain provides a useful guide for similar analysis of autocatalytic self-cleavage reactions.

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Nucleotides in Yeast tRNA ^Phe Required for the Specific Recognition by Its Cognate Synthetase

Sampson

DiRenzo

Behlen

et al. 1989

Science

189

150

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A thermodynamic analysis of the sequence-specific binding of RNA by bacteriophage MS2 coat protein

Johansson

Dertinger²,

LeCuyer³

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

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Most mutations in the sequence of the RNA hairpin that specifically binds MS2 coat protein either reduce the binding affinity or have no effect. However, one RNA mutation, a uracil to cytosine change in the loop, has the unusual property of increasing the binding affinity to the protein by nearly 100-fold. Guided by the structure of the protein-RNA complex, we used a series of protein mutations and RNA modifications to evaluate the thermodynamic basis for the improved affinity: The tight binding of the cytosine mutation is due to (i) the amino group of the cytosine residue making an intra-RNA hydrogen bond that increases the propensity of the free RNA to adopt the structure seen in the complex and (ii) the increased affinity of hydrogen bonds between the protein and a phosphate two bases away from the cytosine residue. The data are in good agreement with a recent comparison of the cocrystal structures of the two complexes, where small differences in the two structures are seen at the thermodynamically important sites.

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Role of the tertiary nucleotides in the interaction of yeast phenylalanine tRNA with its cognate synthetase

Sampson¹,

DiRenzo²,

Behlen³

et al. 1990

Biochemistry

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In vitro transcription by T7 RNA polymerase was used to prepare 32 different mutations in the 21 nucleotides that participate in the 9 tertiary base pairs or triples of yeast tRNAPhe. The mutations were designed either to disrupt the tertiary interaction or to change the sequence without disrupting the structure by transplanting tertiary interactions present in other tRNAs. Steady-state aminoacylation kinetics with purified yeast phenylalanyl synthetase revealed little change in reaction rate as long as a tertiary interaction was maintained. This suggests that the tertiary nucleotides only contribute to the folding of tRNAPhe and do not participate directly in sequence-specific interaction with the synthetase.

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Linda S. Behlen

The contributions of dsRNA structure to Dicer specificity and efficiency

Lead-catalyzed cleavage of yeast tRNAPhe mutants

Nucleotides in Yeast tRNA ^Phe Required for the Specific Recognition by Its Cognate Synthetase

A thermodynamic analysis of the sequence-specific binding of RNA by bacteriophage MS2 coat protein

Role of the tertiary nucleotides in the interaction of yeast phenylalanine tRNA with its cognate synthetase

Contact Info

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Resources

About

Linda S. Behlen

The contributions of dsRNA structure to Dicer specificity and efficiency

Lead-catalyzed cleavage of yeast tRNAPhe mutants

Nucleotides in Yeast tRNA Phe Required for the Specific Recognition by Its Cognate Synthetase

A thermodynamic analysis of the sequence-specific binding of RNA by bacteriophage MS2 coat protein

Role of the tertiary nucleotides in the interaction of yeast phenylalanine tRNA with its cognate synthetase

Contact Info

Product

Resources

About

Nucleotides in Yeast tRNA ^Phe Required for the Specific Recognition by Its Cognate Synthetase