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Abstract The introgression of chromosome segments from wild relatives is an established strategy to enrich crop germplasm with disease-resistance genes 1 . Here we use mutagenesis and transcriptome sequencing to clone the leaf rust resistance gene Lr9 , which was introduced into bread wheat from the wild grass species Aegilops umbellulata 2 . We established that Lr9 encodes an unusual tandem kinase fusion protein. Long-read sequencing of a wheat Lr9 introgression line and the putative Ae. umbellulata Lr9 donor enabled us to assemble the ~28.4-Mb Lr9 translocation and to identify the translocation breakpoint. We likewise cloned Lr58 , which was reportedly introgressed from Aegilops triuncialis 3 , but has an identical coding sequence compared to Lr9 . Cytogenetic and haplotype analyses corroborate that the two genes originate from the same translocation event. Our work sheds light on the emerging role of kinase fusion proteins in wheat disease resistance, expanding the repertoire of disease-resistance genes for breeding. 

Abstract Functional nucleic acids lose activity when their sequence is prepared in the backbone architecture of a different genetic polymer. The only known exception to this rule is a subset of aptamers whose binding mechanism involves G-quadruplex formation. We refer to such examples as transliteration—a synthetic biology concept describing cases in which the phenotype of a nucleic acid molecule is retained when the genotype is written in a different genetic language. Here, we extend the concept of transliteration to include nucleic acid enzymes (XNAzymes) that mediate site-specific cleavage of an RNA substrate. We show that an in vitro selected 2′-fluoroarabino nucleic acid (FANA) enzyme retains catalytic activity when its sequence is prepared as α-l-threofuranosyl nucleic acid (TNA), and vice versa, a TNA enzyme that remains functional when its sequence is prepared as FANA. Structure probing with DMS supports the hypothesis that FANA and TNA enzymes having the same primary sequence can adopt similarly folded tertiary structures. These findings provide new insight into the sequence-structure-function paradigm governing biopolymer folding. 

Abstract Synthetic genetics is an area of synthetic biology that aims to extend the properties of heredity and evolution to artificial genetic polymers, commonly known as xeno‐nucleic acids or XNAs. In addition to establishing polymerases that are able to convert genetic information back and forth between DNA and XNA, efforts are underway to construct XNAs with expanded chemical functionality. α‐L‐Threose nucleic acid (TNA), a type of XNA that is recalcitrant to nuclease digestion and amenable to Darwinian evolution, provides a model system for developing XNAs with functional groups that are not present in natural DNA and RNA. Here, we describe the synthesis and polymerase activity of a cytidine TNA triphosphate analog (6‐phenyl‐pyrrolocytosine, tC^pTP) that maintains Watson‐Crick base pairing with guanine. Polymerase‐mediated primer extension assays show that tC^pTP is an efficient substrate for Kod‐RI, a DNA‐dependent TNA polymerase developed to explore the functional properties of TNA byin vitroselection. Fidelity studies reveal that a cycle of TNA synthesis and reverse transcription occurs with 99.9% overall fidelity when tC^pTP and 7‐deaza‐tGTP are present as TNA substrates. This result expands the toolkit of TNA building blocks available forin vitroselection.