Near-term tropical cyclone risk and coupled Earth system model biases.

Most current climate models predict that the equatorial Pacific will evolve under greenhouse gas-induced warming to a more El Niño-like state over the next several decades, with a reduced zonal sea surface temperature gradient and weakened atmospheric Walker circulation. Yet, observations over the last 50 y show the opposite trend, toward a more La Niña-like state. Recent research provides evidence that the discrepancy cannot be dismissed as due to internal variability but rather that the models are incorrectly simulating the equatorial Pacific response to greenhouse gas warming. This implies that projections of regional tropical cyclone activity may be incorrect as well, perhaps even in the direction of change, in ways that can be understood by analogy to historical El Niño and La Niña events: North Pacific tropical cyclone projections will be too active, North Atlantic ones not active enough, for example. Other perils, including severe convective storms and droughts, will also be projected erroneously. While it can be argued that these errors are transient, such that the models' responses to greenhouse gases may be correct in equilibrium, the transient response is relevant for climate adaptation in the next several decades. Given the urgency of understanding regional patterns of climate risk in the near term, it would be desirable to develop projections that represent a broader range of possible future tropical Pacific warming scenarios-including some in which recent historical trends continue-even if such projections cannot currently be produced using existing coupled earth system models.

Anti-drug Antibody Validation Testing and Reporting Harmonization.

Evolving immunogenicity assay performance expectations and a lack of harmonized anti-drug antibody validation testing and reporting tools have resulted in significant time spent by health authorities and sponsors on resolving filing queries. Following debate at the American Association of Pharmaceutical Sciences National Biotechnology Conference, a group was formed to address these gaps. Over the last 3 years, 44 members from 29 organizations (including 5 members from Europe and 10 members from FDA) discussed gaps in understanding immunogenicity assay requirements and have developed harmonization tools for use by industry scientists to facilitate filings to health authorities. Herein, this team provides testing and reporting strategies and tools for the following assessments: (1) pre-study validation cut point; (2) in-study cut points, including procedures for applying cut points to mixed populations; (3) system suitability control criteria for in-study plate acceptance; (4) assay sensitivity, including the selection of an appropriate low positive control; (5) specificity, including drug and target tolerance; (6) sample stability that reflects sample storage and handling conditions; (7) assay selectivity to matrix components, including hemolytic, lipemic, and disease state matrices; (8) domain specificity for multi-domain therapeutics; (9) and minimum required dilution and extraction-based sample processing for titer reporting.

FDA Approval Summary: Tagraxofusp-erzs For Treatment of Blastic Plasmacytoid Dendritic Cell Neoplasm.

Tagraxofusp-erzs (Elzonris, Stemline) is a cytotoxin that targets CD123-expressing cells. On December 21, 2018, FDA approved tagraxofusp-erzs for the treatment of blastic plasmacytoid dendritic cell neoplasms (BPDCN) in adult and pediatric patients 2 years and older. Approval was based on the response rate in a single-arm trial, Study STML-401-0114; the pivotal cohort included 13 patients with treatment-naïve BPDCN who received tagraxofusp-erzs monotherapy. The complete response or clinical complete response (CR/CRc) rate in the pivotal cohort was 54% (95% CI: 25%-81%), and the median duration of CR/CRc was not reached with a median follow-up of 11.5 months (range: 0.2-12.7). In a separate exploratory cohort, a CR/CRc was achieved by 2 (13%) patients with R/R BPDCN. Safety was assessed in 94 patients with myeloid neoplasms treated with tagraxofusp-erzs at the approved dose and schedule. The major toxicity was capillary leak syndrome (CLS), which occurred in 55% of patients and was fatal in 2%. Hepatotoxicity and hypersensitivity reactions were reported in 88% and 46% of patients, respectively. Other common (≥30%) adverse reactions were nausea, fatigue, peripheral edema, pyrexia, and weight increase. A high proportion of patients (85%) developed neutralizing antidrug antibodies. Tagraxofusp-erzs is the first FDA-approved treatment for BPDCN.

A novel T cell subset with trans-rearranged Vγ-Cß TCRs shows Vß expression is dispensable for lineage choice and MHC restriction.

αß T cells, which express the α-ß TCR heterodimer, express CD4 or CD8 coreceptors on cells that are MHC class I or MHC class II dependent. In contrast, γδ T cells do not express CD4 or CD8 and develop independently of MHC interaction. The factors that determine αß and γδ lineage choice are not fully understood, and the determinants of MHC restriction of TCR specificity have been controversial. In this study we have identified a naturally occurring population of T cells expressing Vγ-Cß receptor chains on the cell surface, the products of genomic trans-rearrangement between the Vγ2 gene and a variety of Dß or Jß genes, in place of an intact TCRß-chain and in association with TCRα. Identification of this population allowed an analysis of the role of TCR variable regions in determining T cell lineage choice and MHC restriction. We found that Vγ2(+)Cß(+) cells are positive for either CD4 or CD8 and are selected in an MHC class II- or MHC class I-dependent manner, respectively, thus following the differentiation pathway of αß and not γδ cells and demonstrating that Vß V region sequences are not required for selection of an MHC-restricted repertoire.

ATM influences the efficiency of TCRß rearrangement, subsequent TCRß-dependent T cell development, and generation of the pre-selection TCRß CDR3 repertoire.

Generation and resolution of DNA double-strand breaks is required to assemble antigen-specific receptors from the genes encoding V, D, and J gene segments during recombination. The present report investigates the requirement for ataxia telangiectasia-mutated (ATM) kinase, a component of DNA double-strand break repair, during TCRß recombination and in subsequent TCRß-dependent repertoire generation and thymocyte development. CD4(-)CD8(-) double negative stage 2/3 thymocytes from ATM-deficient mice have both an increased frequency of cells with DNA break foci at TCRß loci and reduced Vß-DJß rearrangement. Sequencing of TCRß complementarity-determining region 3 demonstrates that ATM-deficient CD4(+)CD8(+) double positive thymocytes and peripheral T cells have altered processing of coding ends for both in-frame and out-of-frame TCRß rearrangements, providing the unique demonstration that ATM deficiency alters the expressed TCRß repertoire by a selection-independent mechanism. ATMKO thymi exhibit a partial developmental block in DN cells as they negotiate the ß-selection checkpoint to become double negative stage 4 and CD4(+)CD8(+) thymocytes, resulting in reduced numbers of CD4(+)CD8(+) cells. Importantly, expression of a rearranged TCRß transgene substantially reverses this defect in CD4(+)CD8(+) cells, directly linking a requirement for ATM during endogenous TCRß rearrangement to subsequent TCRß-dependent stages of development. These results demonstrate that ATM plays an important role in TCRß rearrangement, generation of the TCRß CDR3 repertoire, and efficient TCRß-dependent T cell development.

Concurrent V(D)J recombination and DNA end instability increase interchromosomal trans-rearrangements in ATM-deficient thymocytes.

During the CD4(-)CD8(-) (DN) stage of T-cell development, RAG-dependent DNA breaks and V(D)J recombination occur at three T-cell receptor (TCR) loci: TCRß, TCRγ and TCRδ. During this stage, abnormal trans-rearrangements also take place between TCR loci, occurring at increased frequency in absence of the DNA damage response mediator ataxia telangiectasia mutated (ATM). Here, we use this model of physiologic trans-rearrangement to study factors that predispose to rearrangement and the role of ATM in preventing chromosomal translocations. The frequency of DN thymocytes with DNA damage foci at multiple TCR loci simultaneously is increased 2- to 3-fold in the absence of ATM. However, trans-rearrangement is increased 10 000- to 100 000-fold, indicating that ATM function extends beyond timely resolution of DNA breaks. RAG-mediated synaptic complex formation occurs between recombination signal sequences with unequal 12 and 23 base spacer sequences (12/23 rule). TCR trans-rearrangements violate this rule, as we observed similar frequencies of 12/23 and aberrant 12/12 or 23/23 recombination products. This suggests that trans-rearrangements are not the result of trans-synaptic complex formation, but they are instead because of unstable cis synaptic complexes that form simultaneously at distinct TCR loci. Thus, ATM suppresses trans-rearrangement primarily through stabilization of DNA breaks at TCR loci.

Three nicotine demethylase genes mediate nornicotine biosynthesis in Nicotiana tabacum L.: functional characterization of the CYP82E10 gene.

In most tobacco (Nicotiana tabacum L.) plants, nornicotine is a relatively minor alkaloid, comprising about 2-5% of the total pyridine alkaloid pool in the mature leaf. Changes in gene expression at an unstable locus, however, can give rise to plants that produce high levels of nornicotine, specifically during leaf senescence and curing. Minimizing the nornicotine content in tobacco is highly desirable, because this compound serves as the direct precursor in the synthesis of N'-nitrosonornicotine, a potent carcinogen in laboratory animals. Nornicotine is likely produced almost entirely via the N-demethylation of nicotine, in a process called nicotine conversion that is catalyzed by the enzyme nicotine N-demethylase (NND). Previous studies have identified CYP82E4 as the specific NND gene responsible for the unstable conversion phenomenon, and CYP82E5v2 as a putative minor NND gene. Here, by discovery and characterization of CYP82E10, a tobacco NND gene, is reported. PCR amplification studies showed that CYP82E10 originated from the N. sylvestris ancestral parent of modern tobacco. Using a chemical mutagenesis strategy, knockout mutations were induced and identified in all three tobacco NND genes. By generating a series of mutant NND genotypes, the relative contribution of each NND gene toward the nornicotine content of the plant was assessed. Plants possessing knockout mutations in all three genes displayed nornicotine phenotypes that were much lower (∼0.5% of total alkaloid content) than that found in conventional tobacco cultivars. The introduction of these mutations into commercial breeding lines promises to be a viable strategy for reducing the levels of one of the best characterized animal carcinogens found in tobacco products.

CYP82E4-mediated nicotine to nornicotine conversion in tobacco is regulated by a senescence-specific signaling pathway.

Nicotine to nornicotine conversion in tobacco (Nicotiana tabacum L.) is regulated by an unstable converter locus which in its activated state gives rise to a high nornicotine, low nicotine phenotype in the senescing leaves. In plants that carry the high nornicotine trait, nicotine conversion is primarily catalyzed by a cytochrome P450 protein, designated CYP82E4 whose transcription is strongly upregulated during leaf senescence. To further investigate the regulation of CYP82E4 expression, we examined the spatiotemporal distribution and the stress- and signaling molecule-elicited expression patterns of CYP82E4 using alkaloid analysis and a fusion construct between the 2.2 kb upstream regulatory region of CYP82E4 and the beta-glucurodinase (GUS) gene. Histochemical and fluorometric analyses of GUS expression revealed that the CYP82E4 promoter confers high levels of expression in the senescing leaves and flowers, and in the green stems of young and mature plants, but only very low activity was detected in the roots. In the leaves, GUS activity was strongly correlated with the progression of senescence. Treatments of leaf tissue with various signaling molecules including abscisic acid, ethylene, jasmonic acid, salicylic acid and yeast extract; and stresses, such as drought, wounding and tobacco mosaic virus infection did not enhance nicotine conversion or GUS activity in the green leaves, but an increase in CYP82E4 expression was observed in response to ethylene- or tobacco mosaic virus-induced senescence. These results suggest that the expression of CYP82E4 is senescence-specific in the leaves and the use of the CYP82E4 promoter could provide a valuable tool for regulating gene expression in the senescing leaves.

Functional analysis of nicotine demethylase genes reveals insights into the evolution of modern tobacco.

Tobacco (Nicotiana tabacum L.) is a natural allotetraploid derived from the interspecific hybridization between ancestral Nicotiana sylvestris and Nicotiana tomentosiformis. The majority of cultivated tobacco differs from both of its progenitor species in that tobacco typically contains nicotine as the primary alkaloid, in contrast to its two progenitors that accumulate nornicotine in the senescing leaves. However, most, if not all, tobacco cultivars possess an unstable mutation, commonly referred to as the conversion locus, that when activated mediates the conversion of a large percentage of nicotine to nornicotine in the senescing leaf. We have recently identified CYP82E4, a tobacco nicotine N-demethylase gene whose expression was highly induced during senescence in plants that have converted, and CYP82E3, a closely related homolog that exhibited no nicotine N-demethylase activity. In this study, domain swapping and site-directed mutagenesis studies identified a single amino acid change that fully restored nicotine N-demethylase activity to CYP82E3. An examination of the N. tomentosiformis orthologs of CYP82E3 and CYP82E4 revealed that both are functional nicotine N-demethylase genes in N. tomentosiformis. Collectively, our results suggest that a single base pair mutation in CYP82E3 and transcriptional suppression of CYP82E4 played important roles in the evolution of the alkaloid profile characteristic of modern tobacco.

Conversion of nicotine to nornicotine in Nicotiana tabacum is mediated by CYP82E4, a cytochrome P450 monooxygenase.

Nornicotine is a secondary tobacco alkaloid that is produced by the N-demethylation of nicotine. Nornicotine production and accumulation in tobacco are undesirable because nornicotine serves as the precursor in the synthesis of the well characterized carcinogen N'-nitrosonornicotine during the curing and processing of tobacco. Although nornicotine is typically a minor alkaloid in tobacco plants, in many tobacco populations a high percentage of individuals can be found that convert a substantial proportion of the nicotine to nornicotine during leaf senescence and curing. We used a microarray-based strategy to identify genes that are differentially regulated between closely related tobacco lines that accumulate either nicotine (nonconverters) or nornicotine (converters) as the predominant alkaloid in the cured leaf. These experiments led to the identification of a small number of closely related cytochrome P450 genes, designated the CYP82E2 family, whose collective transcript levels were consistently higher in converter versus nonconverter tobacco lines. RNA interference-induced silencing of the CYP82E2 gene family suppressed the synthesis of nornicotine in strong converter plants to levels similar to that observed in nonconverter individuals. Although each of the six identified members of the P450 family share >90% nucleotide sequence identity, sense expression of three selected isoforms revealed that only one (CYP82E4v1) was involved in the conversion of nicotine to nornicotine. Yeast expression analysis revealed that CYP82E4v1 functions as a nicotine demethylase. Identification of the gene(s) responsible for nicotine demethylation provides a potentially powerful tool toward efforts to minimize nornicotine levels, and thereby N'-nitrosonornicotine formation, in tobacco products.

Molecular characterization and functional analysis of the manganese-containing superoxide dismutase gene (sodA) from Streptococcus thermophilus AO54.

This report describes the isolation, sequencing, and functional analysis of the sodA gene, encoding Mn-superoxide dismutase, from Streptococcus thermophilus AO54. The gene was found to encode a 201 amino acid polypeptide with 88 and 83% identity to SodA from Streptococcus mutans and Streptococcus agalacticae, respectively. Primer extension analysis revealed a transcriptional start site 27 nucleotides upstream of initiation codon. The gene was expressed in Escherichia coli and was able to rescue the growth of a sodAsodB mutant in a minimal-medium containing 10(-6)M paraquat. A sodA mutant of S. thermophilus was constructed and found to be more sensitive to aerobic growth than its parent strain. Supplementing the medium with MnCl(2) improved the growth of the mutant, only under microaerophilic conditions. The results suggest that sodA is essential for the aerobic growth of S. thermophilus. In the absence of functional SodA, manganese ions may provide partial protection against oxygen toxicity.