Modified physiology of burley tobacco plants genetically engineered to express Yb1, a functional EGY enzyme.

MAIN CONCLUSION: Transgenic overexpression of a NtEGY2 gene restores normal green color of burley tobacco plants, but does not increase nitrogen utilization efficiency beyond that exhibited by wild-type individuals. Nitrogen physiology is important in tobacco because of its role in generation of leaf yield and accumulation of nitrogen-containing alkaloids that can react with nitrosating agents in the formation of carcinogenic tobacco-specific nitrosamines. Cultivars of the burley tobacco market class are homozygous for deleterious mutant alleles at the duplicate Yb1 and Yb2 loci which have previously been associated with decreased nitrogen use and utilization efficiency; increased leaf nitrate, total nitrogen, and alkaloid levels; and reduced yields. How mutant alleles at these two loci affect these traits is not well understood. Recent characterization of the Yb1 and Yb2 genes (homologs of Arabidopsis EGY1 gene) enabled overexpression of the wild-type Yb1 allele in yb1yb1yb2yb2 plants to determine if observed unfavorable effects were due to linkage or pleiotropy, and to determine if overexpression could lead to beneficial modifications in any of these traits in transgenic plants relative to naturally-occurring wild-type genotypes. Yb1 overexpression was found to confer an agronomic benefit to yb1yb1yb2yb2 genotypes but no advantage to wild-type genotypes. RNA-Seq was used to carry out a comparative transcriptome analysis of genetically engineered and wild-type nearly isogenic lines (NILs) to gain insight on metabolic pathways affecting carbon and nitrogen metabolism that might be altered as the result of genetic variability at the Yb1 and Yb2 loci. Results indicate that complex changes in the transcriptome of tobacco can be manifested by altered expression of Yb1.

Combined reduced expression of two gene families lowers nicotine content to ultra-low levels in cultivated tobacco.

KEY MESSAGE: Reduced expression of two gene families results in ultra-low nicotine accumulation in Nicotiana tabacum. The potential for mandated lowering of tobacco cigarette filler nicotine levels to below 0.4 mg g-1 is currently being discussed by regulatory and public health organizations. Commercial tobacco cultivars that would routinely meet this proposed standard do not currently exist. Inactivation or silencing of gene families corresponding to single enzymatic steps in the nicotine biosynthetic pathways have not resulted in tobacco genotypes that would meet this standard under conventional agronomic management. Here, we produced and evaluated under field conditions tobacco genotypes expressing an RNAi construct designed to reduce expression of the Methyl Putrescine Oxidase (MPO) gene family associated with nicotine biosynthesis. In a standard flue-cured genetic background, cured leaf nicotine levels were reduced to only 1.08 to 1.65 mg g-1. When MPO RNAi was combined with reduced Berberine Bridge Like (BBL) activity conferred by induced mutations, genotypes producing cured leaf nicotine levels slightly lower than 0.4 mg g-1 were generated. Past research has suggested that MPO activity may contribute to the biosynthesis of nornicotine in a route that does not involve nicotine. However, nornicotine was not reduced to zero in MPO-silenced plants that were also homozygous for induced mutations in known Nicotine Demethylase genes that are responsible for the vast majority of nornicotine accumulation.

Editing of A622 genes results in ultra-low nicotine whole tobacco plants at the expense of dramatically reduced growth and development.

Due to potential regulations that could affect nicotine levels in some tobacco products, there is interest in using genetic modification to reduce levels of this pyridine alkaloid in tobacco leaves. Enzymes coded by A622 genes have previously been indicated to be involved in one of the latter steps of tobacco alkaloid biosynthesis. Whole tobacco plants with reduced A622 activity have never been evaluated, however. We utilized CRISPR/Cas9-based editing to introduce deleterious mutations into the two A622 genes present in the Nicotiana tabacum genome. Double homozygous A622 mutant genotypes established in four recipient genotypes varying for the presence/absence of mutations in other alkaloid biosynthetic genes exhibited severely reduced nicotine accumulation in field and greenhouse experiments. A622 knockout lines exhibited lower nicotine levels than previously created genotypes with deleterious mutations in BBL genes also associated with one of the latter steps in tobacco alkaloid biosynthesis. Reduced A622 activity resulted in plants with drastically reduced growth and development, however. A622 mutant lines were later flowering and produced green leaf yields that were 60.6% lower, on average, than those for non-A622-mutated control lines. Supplementary Information: The online version contains supplementary material available at 10.1007/s11032-022-01293-w.

Analyses of diverse low alkaloid tobacco germplasm identify naturally occurring nucleotide variability contributing to reduced leaf nicotine accumulation.

Recent suggestions for mandated lowering of nicotine content in cigarettes have prompted tobacco breeders to search for N. tabacum germplasm with allelic variability contributing to low alkaloid accumulation. In this research, we phenotyped a series of 81 selected diverse tobacco introductions (TIs) to identify a sub-group with authentic low alkaloid phenotypes. We also genotyped these materials for sequences associated with the Nic1 and Nic2 loci previously reported to influence tobacco alkaloid biosynthesis. Only five low alkaloid TIs possessed previously described deletions of Ethylene Response Factor (ERF) genes at the Nic2 locus that contribute to lower alkaloid accumulation. Eleven TIs possessed an apparent deletion of ERF199, a gene recently reported to underlie the effect at the Nic1 locus. Quantitative trait locus (QTL) mapping was performed using populations derived from three selected low alkaloid TIs to possibly identify new genomic regions affecting alkaloid accumulation. A major QTL was identified on linkage group 7 in all three populations that aligned with the Nic1 locus. A newly discovered 5 bp deletion in the gene MYC2a on linkage group 5 was found to likely partially underlie the ultra-low alkaloid phenotype of TI 313. This new information is useful for tobacco breeders attempting to assemble novel genetic combinations with the potential for meeting future levels of tolerance for nicotine concentration in cigarette tobacco. Supplementary Information: The online version contains supplementary material available at 10.1007/s11032-021-01274-5.

Identification and editing of a hybrid lethality gene expands the range of interspecific hybridization potential in Nicotiana.

KEY MESSAGE: Identification and inactivation of hybrid lethality genes can be used to expand the available gene pool for improvement of a cultivated crop species. Hybrid lethality is one genetic mechanism that contributes to reproductive isolation in plants and serves as a barrier to use of diverse germplasm for improvement of cultivated species. A classic example is the seedling lethality exhibited by progeny from the Nicotiana tabacum × N. africana interspecific cross. In order to increase the body of knowledge on mechanisms of hybrid lethality in plants, and to potentially develop tools to circumvent them, we utilized a transposon tagging strategy to identify a candidate gene involved in the control of this reaction. N. tabacum gene Nt6549g30 was identified to code for a class of coiled-coil nucleotide-binding site-leucine-rich repeat (CC-NBS-LRR) proteins, the largest class of plant defense proteins. Gene editing, along with other experiments, was used to verify that Nt6549g30 is the gene at the N. tabacum Hybrid Lethality 1 (NtHL1) locus controlling the hybrid lethality reaction in crosses with N. africana. Gene editing of Nt6549g30 was also used to reverse interspecific seedling lethality in crosses between N. tabacum and eight of nine additional tested species from section Suaveolentes. Results further implicate the role of disease resistance-like genes in the evolution of plant species and demonstrate the possibility of expanding the gene pool for a crop species through gene editing.

The Tobacco Trichome Exudate Z-abienol and Its Relationship With Plant Resistance to Phytophthora nicotianae.

In previous research, we discovered a favorable quantitative trait locus (QTL) in cigar tobacco cultivar 'Beinhart 1000' designated as Phn15.1, which provides a high level of partial resistance to the black shank disease caused by Phytophthora nicotianae. A very close genetic association was also found between Phn15.1 and the ability to biosynthesize Z-abienol, a labdanoid diterpene exuded by the trichomes onto above-ground plant parts, and that imparts flavor and aroma characteristics to Oriental and some cigar tobacco types. Because accumulation of Z-abienol is considered to be undesirable for cultivars of other tobacco types, we herein describe a series of experiments to gain insight on whether this close association is due to genetic linkage or pleiotropy. First, in an in vitro bioassay, we observed Z-abienol and related diterpenes to inhibit hyphal growth of P. nicotianae at concentrations between 0.01 and 100 ppm. Secondly, we field-tested transgenic versions of Beinhart 1000 carrying RNAi constructs for downregulating NtCPS2 or NtABS, two genes involved in the biosynthesis of Z-abienol. Thirdly, we also field tested a recombinant inbred line population segregating for a truncation mutation in NtCPS2 leading to an interrupted Z-abienol pathway. We observed no correlation between field resistance to P. nicotianae and the ability to accumulate Z-abienol in either the transgenic materials or the mapping population. Results suggest that, although Z-abienol may affect P. nicotianae when applied at high concentrations in in vitro assays, the compound has little effect on black shank disease development under natural field conditions. Thus, it should be possible to disassociate Phn15.1-mediated black shank resistance identified in cigar tobacco cultivar Beinhart 1000 from the ability to accumulate Z-abienol, an undesirable secondary metabolite for burley and flue-cured tobacco cultivars.

Genetic markers unique to Listeria monocytogenes serotype 4b differentiate epidemic clone II (hot dog outbreak strains) from other lineages.

A small number of closely related strains of Listeria monocytogenes serotype 4b, designated epidemic clone I (ECI), have been implicated in numerous outbreaks of food-borne listeriosis described during the past two decades in Europe and North America. In 1998 to 1999, a multistate outbreak traced to contaminated hot dogs involved a different strain type of serotype 4b, with genetic fingerprints rarely encountered before. In spite of the profound economic and public health impact of this outbreak, the implicated bacteria (designated epidemic clone II [ECII]) have remained poorly characterized genetically, and nucleotide sequences specific for these strains have not been reported. Using genome sequence information, PCR, and Southern blots, we identified DNA fragments which appeared to be either absent or markedly divergent in the hot dog outbreak strains but conserved among other serotype 4b strains. PCR with primers derived from these fragments as well as Southern blots with the amplicons as probes readily differentiated ECII from other serotype 4b strains. The serotype 4b-specific region harboring these fragments was adjacent to inlA, which encodes a well-characterized virulence determinant. The findings suggest that ECII strains have undergone divergence in portions of a serotype-specific region that is conserved in other serotype 4b strains. Although the mechanisms that drive this divergence remain to be identified, DNA-based tools from this region can facilitate the detection and further characterization of strains belonging to this lineage.

Salt-induced antioxidant metabolism defenses in maize (Zea mays L.) seedlings.

Salinity alters general metabolic processes and enzymatic activities, causing increased production of reactive oxygen species (ROS). Expression of antioxidant defense genes would, in turn, be triggered to defend the cell against oxidative damage. We report that salt disturbed antioxidant metabolism in maize seedlings, causing detrimental effects on the growth and development of maize plantlets, increased hydrogen peroxide production and altered antioxidant activities and transcripts profiles. Excessive ROS levels were accompanied by increased catalase (CAT) activity in photosynthesizing shoots, along with induction of mRNA accumulation. Increased accumulation of superoxide dismutase (SOD) transcripts was also observed although no significant changes in total SOD enzymatic activity and isozyme profiles were detected. Higher salt concentrations (above 0.25 M NaCl) were highly detrimental to the plants, causing arrested growth and severe wilting, among other effects. Histochemical detection of H(2)O(2) by 3,3-diaminobenzidine (DAB) staining indicated a collapse of the leaf veins, with hydrogen peroxide leaking to neighboring cells. In agreement to these observations, Sod1, Sod2, Sod4, Sod4A, as well as all Cat transcripts were severely inhibited in plants exposed to high salt concentrations.