Five genes induced by aluminum in wheat (Triticum aestivum L.) roots.

Five different cDNAs (termed wali1 to wali5 for Wheat Aluminum Induced) whose expression was induced by Al stress have been isolated from the root tips of Al-treated wheat (Triticum aestivum L.) plants. Four of these genes were induced 24 to 96 h after Al treatment, and their expression is reduced when the Al is removed. Each of these four genes was induced by inhibitory levels of Al in two wheat cultivars--Warigal, an Al-sensitive cultivar, and Waalt, an Al-tolerant cultivar. The fifth gene (wali2) showed a complex bimodal pattern of induction and was induced by Al only in the sensitive cultivar. Comparison of the nucleotide sequences of these clones to those in the sequence data bases showed that wali4 is homologous to phenylalanine ammonia-lyase and wali1 is homologous to a group of plant proteins that are cysteine-rich and have homology to metallothioneins. wali2 encodes a novel protein with a repeating motif of cysteine amino acids. The remaining two wali clones (wali3 and wali5) encode related, cysteine-rich proteins that show no significant homology to any known sequences.     

Complementation of bacteriophage lambda integrase mutants: evidence for an intersubunit active site.

Site-specific recombination of bacteriophage lambda starts with the formation of higher-order protein--DNA complexes, called 'intasomes', and is followed by a series of steps, including the initial DNA cleavage, top-strand exchange, branch migration and bottom-strand exchange, to produce recombinant products. One of the intasomes formed during excisive recombination (the attL complex) is composed of the phage-encoded integrase (Int), integration host factor (IHF) and one of the recombination substrates, attL DNA. Int is the catalytic recombinase and has two different DNA binding domains. When IHF is present, Int binds to two types of sites in attL DNA, the three arm-type sites (P'123) and the core-type sites (B and C') where the reciprocal strand exchange takes place. The Tyr342 residue of Int serves as a nucleophile during strand cleavage and covalently attaches to the DNA through a phosphotyrosyl bond. In vitro complementation assays have been performed for strand cleavage using attL suicide substrates and mutant proteins containing amino acid substitutions at residues conserved in the integrase family of recombinases. We demonstrate that at least two Int monomers are required to form the catalytically-competent species that performs cleavage at the B site. It is likely that the active site is formed by two Int monomers.     

Prediction of near-term climate change impacts on UK wheat quality and the potential for adaptation through plant breeding

Wheat is a major crop worldwide, mainly cultivated for human consumption and animal feed. Grain quality is paramount in determining its value and downstream use. While we know that climate change threatens global crop yields, a better understanding of impacts on wheat end-use quality is also critical. Combining quantitative genetics with climate model outputs, we investigated UK-wide trends in genotypic adaptation for wheat quality traits. In our approach, we augmented genomic prediction models with environmental characterisation of field trials to predict trait values and climate effects in historical field trial data between 2001 and 2020. Addition of environmental covariates, such as temperature and rainfall, successfully enabled prediction of genotype by environment interactions (G × E), and increased prediction accuracy of most traits for new genotypes in new year cross validation. We then extended predictions from these models to much larger numbers of simulated environments using climate scenarios projected under Representative Concentration Pathways 8.5 for 2050–2069. We found geographically varying climate change impacts on wheat quality due to contrasting associations between specific weather covariables and quality traits across the UK. Notably, negative impacts on quality traits were predicted in the East of the UK due to increased summer temperatures while the climate in the North and South-west may become more favourable with increased summer temperatures. Furthermore, by projecting 167,040 simulated future genotype–environment combinations, we found only limited potential for breeding to exploit predictable G × E to mitigate year-to-year environmental variability for most traits except Hagberg falling number. This suggests low adaptability of current UK wheat germplasm across future UK climates. More generally, approaches demonstrated here will be critical to enable adaptation of global crops to near-term climate change.     

Regeneration of transgenic tamarillo plants

Media were developed to regenerate shoots from leaf pieces of tamarillo (Cyphomandra betacea (Cav.) Sendtner). Shoots were derived via organogenesis and could be easily rooted and transferred to the growth chamber. Transgenic tamarillo plants were produced using the binary vector pKIWI110 in the avirulent Agrobacterium strain LBA4404. All transgenic plants were kanamycin resistant and some plants expressed the D-glucuronidase (gusA) reporter gene and were chlorsulfuron resistant. Molecular evidence for transformation was obtained using PCR (polymerase chain reaction) and Southern hybridization. Inheritance of the transgenic phenotypes was demonstrated in seedling progeny.     

Development of DNA methylation-based epigenetic age predictors in loblolly pine (Pinus taeda)

Biological ageing is connected to life history variation across ecological scales and informs a basic understanding of age-related declines in organismal function. Altered DNA methylation dynamics are a conserved aspect of biological ageing and have recently been modelled to predict chronological age among vertebrate species. In addition to their utility in estimating individual age, differences between chronological and predicted ages arise due to acceleration or deceleration of epigenetic ageing, and these discrepancies are linked to disease risk and multiple life history traits. Although evidence suggests that patterns of DNA methylation can describe ageing in plants, predictions with epigenetic clocks have yet to be performed. Here, we resolve the DNA methylome across CpG, CHG, and CHH-methylation contexts in the loblolly pine tree (Pinus taeda) and construct epigenetic clocks capable of predicting ages in this species within 6% of its maximum lifespan. Although patterns of CHH-methylation showed little association with age, both CpG and CHG-methylation contexts were strongly associated with ageing, largely becoming hypomethylated with age. Among age-associated loci were those in close proximity to malate dehydrogenase, NADH dehydrogenase, and 18S and 26S ribosomal RNA genes. This study reports one of the first epigenetic clocks in plants and demonstrates the universality of age-associated DNA methylation dynamics which can inform conservation and management practices, as well as our ecological and evolutionary understanding of biological ageing in plants.     

Biology and life cycle ofAtelocauda koae,an unusual demicyclic rust

Atelocauda koae, a rust of the native HawaiianAcacia koa, is considered as a demicyclic species, having spermogonial, aecial, and telial states, but is unusual in production of aeciospores simultaneously with teliospores rather than consecutively. Host inoculation with spores of each state separately confirmed that the life cycle was perpetuated by the telial state, but the aeciospores, while capable of germination and stomal penetration, did not produce detectable infection. This rust therefore behaves as a microcyclic species, and appears to be in evolutionary transition toward this reduced state. Teliospores produced vestigial, permanently attached basidiosopores which germinated to produce infective hyphae. The hyphae entered the host either through stomata or penetrated the epidermis directly, with the latter method being more common. Unusual nuclear associated with teliospore germination, in which meiosis occurs in more than one diploid nucleus was observed, in confirmation of an earlier study.     

Resistance to Vanilla Necrosis Potyvirus in Transgenic Nicotiana benthamiana Plants Containing the Virus Coat Protein Gene

The full-length vanilla necrosis potyvirus (VNV) coat protein (CP) gene was introduced into Nicotiana benthamiana plants via Agrobacterium tumefaciens-mediated transformation. Four constructs contained either: sense (+) CP sequence, antisense (-) CP sequence, sense CP sequence with a Kozak's consensus ATG resulting in a change in the first amino acid, or antisense CP sequence with the Kozak's modification. When mechanically inoculated with a high concentration of VNV, one of the plant lines containing the full-length sense CP gene was highly resistant to virus infection. Plants from the resistant lines expressed the CP at a relatively low level compared to susceptible lines containing the same construct. Plants containing the other three constructs were either susceptible or showed delayed symptom expression.