ELICE16INDURES ®: a plant immune-priming activator targeting jasmonate metabolism via TIFY and RHOMBOID proteins in Hordeum vulgare

Priming activity of plant-based allelochemicals is advanced research nowadays meaning a high potential in sustainable agriculture. The ELICE16INDURES® (RIMPH LTD, Hungary) plant conditioner of CO2 botanical extracts is rich in plant-active ingredients such as phenolic compounds, alkaloids, and flavonoids formulated in small multilamellar liposomes. This product was investigated in autumn barley (Hordeum vulgare). Field experiments of ELICE16INDURES showed augmented NDVI values interconnected with higher photosynthetic activity and yield increase. Background of the better vitality of plants was investigated by whole genomic gene expression profiling and showed an enhanced response to wounding, jasmonic acid, oxidative detoxification, and chloroplast activity. Among top 50 differentially expressed genes the TIFY domain protein TIFY11B and RHOMBOID-like protein 2 related to JA signaling were up-regulated in field-collected samples. Phytotron experiments of barley were set up to validate and evaluate the transcriptomic effect of ELICE16INDURES. Well-studied priming active agents such as salicylic acid and beta-aminobutyric acid were compared with ELICE16INDURES and confirmed as priming inducer material with positive regulation of TIFY11B, TIFY3B, TIFY9, TIF10A, and RHOMBOID like protein 2 by using NGS GEx and RT-qPCR methods.

Comparative analysis of the characteristics of Haplorchis taichui mitochondrial genome with Metagonimus yokogawai and its ribosomal transcription unit with H. pumilio (family Heterophyidae)

Minute intestinal flukes, Haplorchis taichui and H. pumilio, belong to the family Heterophyidae (Trematoda: Platyhelminthes), which have been studied very limited, especially the molecular markers of the mitochondrial genomes (mtDNA) and the ribosome transcription units (rTU or rDNA). We have obtained the complete mitochondrial genome of H. taichui and the coding part of ribosome transcription unit of H. taichui and H. pumilio of Vietnam. Nucleotide and amino acid data were compared between H. taichui and Metagonimus yokogawai for genomic/gene composition, codon usage (skew/skewness), and tandem repeat units (TRU). The complete mtDNA of H. taichui (strain Htai-QT3-VN) with the length of 15,120 bp and M. yokogawai (15,258 bp; Korea; KC330755) contains 36 genes, including 12 protein-coding genes (cox1, cox2, cox3, nad1, nad2, nad3, nad4L, nad4, nad5, nad6, atp6 and cob), 2 ribosomal RNA genes (rRNA); 22 transfer RNA (tRNA or trn) and a noncoding region (NCR) between trnE and trnG, divided into 2 sub-regions containing 5 TRUs (182–183 bp/TRU). H. taichui (Vietnam and Laos) uses A = 19.56%, T = 39.71%, G = 28.34%, C = 12.39% (A + T is 59.27% ​​and G + C is 40.73%) for mtDNA construction, whose skew/skewness value at A+T is negative (–0,340) and G+C is positive (0.392); for 12 protein-coding genes (PCGs) is similar; but for the mito-ribosomal genes (MRGs, of 16S/rrnL and 12S/rrnS) it is less for A+T (57.22%) and more for G+C (42.78%). M. yokogawai had lower A+T (mtDNA/55.68%; PCGs/55.96%; MRGs/54.15%) and higher G+C usage rate than H. taichui. H. taichui of Vietnam and Laos has 10,164 bp encoding for 3,376 amino acids to construct 12 PCGs with the mostly used codons as Phenylalanine (Phe-TTT) and Leucine (Leu-TTG), and the leastly used codonsas Glutamine (Gln-CAA), Arginine (Arg-CGC). Additional condon, Thr-ACA/ACC can be added as the least used in M. yokogawai. The rTU (from 5 '18S to 3' 28S) of H. taichui (7,268 bp) and H. pumilio (7,416 bp) were identified with 5 genomic regions including 18S rDNA, ITS1, 5.8S rDNA, ITS2 and 28S rDNA. The 18S and 5.8S genes of both species were of the same length (1,992 bp for 18S, 160 bp for 5.8S), but different for 28S genes (3,875 bp for H. taichui and 3,870 bp for H. pumilio). ITS1 in H. taichui (797 bp) and ITS2 in H. pumilio (280 bp) do not contain TRUs, whilst ITS1 in H. pumilio (1,106 bp) contains 5 TRUs(136 bp for 3 TRU and 116 bp for 2 TRUs); and ITS2 in H. taichui (444 bp) contain 3 TRUs (83–85 bp/each).

Genotype to Phenotype: CRISPR Gene Editing Reveals Genetic Compensation as a Mechanism for Phenotypic Disjunction of Morphants and Mutants

Forward genetic screens have shown the consequences of deleterious mutations; however, they are best suited for model organisms with fast reproductive rates and large broods. Furthermore, investigators must faithfully identify changes in phenotype, even if subtle, to realize the full benefit of the screen. Reverse genetic approaches also probe genotype to phenotype relationships, except that the genetic targets are predefined. Until recently, reverse genetic approaches relied on non-genomic gene silencing or the relatively inefficient, homology-dependent gene targeting for loss-of-function generation. Fortunately, the flexibility and simplicity of the clustered regularly interspaced short palindromic repeats (CRISPR)/Cas system has revolutionized reverse genetics, allowing for the precise mutagenesis of virtually any gene in any organism at will. The successful integration of insertions/deletions (INDELs) and nonsense mutations that would, at face value, produce the expected loss-of-function phenotype, have been shown to have little to no effect, even if other methods of gene silencing demonstrate robust loss-of-function consequences. The disjunction between outcomes has raised important questions about our understanding of genotype to phenotype and highlights the capacity for compensation in the central dogma. This review describes recent studies in which genomic compensation appears to be at play, discusses the possible compensation mechanisms, and considers elements important for robust gene loss-of-function studies.

Hyperprogression in cancer patients on immunotherapeutic agents.

3575 Background: Patients (pts) treated with checkpoint inhibitors (CPI) may uncommonly experience accelerated progression in their tumor burden when compared to their rate of progression prior to receiving CPI. This hyperprogression has been varyingly defined and no biomarker has yet been identified. Methods: We reviewed the database from the Tumor Response Assessment Core (TRAC) at University of Michigan to identify these patients. Hyperprogression was defined as increase in tumor burden per specific immune RECIST criteria by at least 40% from baseline on the first follow-up scan with a minimum increase of 10 mm, and at least 2 times rate of growth than observed prior to start of CPI therapy. Results: Out of 741 pts who underwent baseline and 1st follow-up assessment enrolled on 118 trials, 302 (34.4%) pts received immunotherapy alone or in combination with chemotherapy/targeted agents across 49 trials. Of them, 15 pts (5%) with 5 females (33%) and median age of 63 years (range, 44 -72) met criteria for hyperprogression. The primary cancers included lung (5), colorectal (2), renal (2), biliary (1), pancreatic (1), esophageal (1), bladder (1), small bowel (1), and melanoma (1). The median time to hyperprogression was 67 (range 42-110) days, and the mean survival was 7.9 months from trial enrollment. We did not identify any clinical factor or specific CPI therapy that associated with hyperprogression. Exploratory biomarker analysis of genomic (gene panel assay) and immune subsets of tissue microenvironment (multiplex staining) is underway. Conclusions: This is the largest cohort investigated for hyperprogression across multiple cancers in literature. The rate of hyperprogression observed is less than previously reported in literature, and physicians need to be aware of this possibility while administering CPI to their patients.

Efficient Gene Targeting in Maize using Inducible CRISPR-Cas9 and Marker-Free Donor Template

CRISPR-Cas9 is a powerful tool for generating targeted mutations and genomic deletions. However, precise gene insertion or sequence replacement remains a major hurdle before application of CRISPR-Cas9 technology is fully realized in plant breeding. Here we report high frequency, selectable marker-free intra-genomic gene targeting (GT) in maize. Heat shock-inducible Cas9 was used for generating targeted double-strand breaks (DSBs) and simultaneous mobilization of the donor template from pre-integrated T-DNA. The construct was designed such that release of the donor template and subsequent DNA repair activated expression of the selectable marker gene within the donor locus. This approach generated up to 4.7% targeted insertion of the donor sequence into the target locus in T0 plants, with up to 86% detected donor template release and 99% mutation rate were observed at the donor loci and the genomic target site, respectively. Unlike previous in planta or intra-genomic homologous recombination reports, that required multiple generations and extensive screening, our method provides non-chimeric, heritable GT in the T0 generation.

CRISPR–Cas12a system in fission yeast for multiplex genomic editing and CRISPR interference

The CRISPR–Cas12a is a class II, type V clustered regularly interspaced short palindromic repeat (CRISPR) system with both RNase and DNase activity. Compared to the CRISPR–Cas9 system, it recognizes T-rich PAM sequences and has the advantage of multiplex genomic editing. Here, in fission yeast Schizosaccharomyces pombe, we successfully implemented the CRISPR–Cas12a system for versatile genomic editing and manipulation. In addition to the rrk1 promoter, we used new pol II promoters from endogenous coding genes to express crRNA for Cas12a and obtained a much higher editing efficiency. This new design expands the promoter choices for potential applications in fission yeast and other organisms. In addition, we expressed a gRNA array using a strong constitutive pol II promoter. The array transcript is processed by Cas12a itself to release multiple mature crRNAs. With this construct, multiplex genomic editing of up to three loci was achieved from a single yeast transformation. We also built a CRISPR interference system using a DNase-dead Cas12a to significantly repress endogenous gene expression. Our study provides the first CRISPR-Cas12a toolkit for efficient and rapid genomic gene editing and regulation in fission yeast.

Comparison of different selection methods for improving litter size in sheep using computer simulation

Aim of study: To assess selection methods via introgression to improve litter size in native and synthetic sheep breeds.Area of study: Sanandaj, Kurdistan, Iran.Material and methods: Selection approaches were performed using classical, genomic, gene-assisted classical (GasClassical) and gene-assisted genomic (GasGenomic) selection. Litter size trait with heritability of 0.1 including two chromosomes was simulated. On chromosome 1, a single QTL as the major gene was created to explain 40% of the total additive genetic variance. After simulation of a historical population, the animals from the last historical population were split into two populations. For the next 7 generations, animals were selected for favorable or unfavorable alleles to create distinct breeds of A or B, respectively. Then from the last generation, both males and females from breed B were selected to create a native population. On the other hand, males from breed A and females from breed B were mated to simulate a synthetic population. Finally, intra-population selections were carried out based on high breeding values during the last five generations.Main results: The genetic gain in the synthetic breed was higher than that of the native breed under all selection methods. The frequencies of favorable alleles after five generations in the classical, genomic, GasClassical and GasGenoimc selection approaches in the synthetic breed were 0.623, 0.730, 0.850 and 0.848, respectively.Research highlights: Combining gene-assisted selection with classical or genomic selection has the potential to improve genetic gain and increase the frequencies of favorable allele for litter size in sheep.

ZMAT2 in Humans and Other Primates: A Highly Conserved and Understudied Gene

Recent advances in genetics present unique opportunities for enhancing our understanding of human physiology and disease predisposition through detailed analysis of gene structure, expression, and population variation via examination of data in publicly accessible genome and gene expression repositories. Yet, the vast majority of human genes remain understudied. Here, we show the scope of these genomic and genetic resources by evaluating ZMAT2, a member of a 5-gene family that through May 2020 had been the focus of only 4 peer-reviewed scientific publications. Using analysis of information extracted from public databases, we show that human ZMAT2 is a 6-exon gene and find that it exhibits minimal genetic variation in human populations and in disease states, including cancer. We further demonstrate that the gene and its encoded protein are highly conserved among nonhuman primates and define a cohort of ZMAT2 pseudogenes in the marmoset genome. Collectively, our investigations illustrate how complementary use of genomic, gene expression, and population genetic resources can lead to new insights about human and mammalian biology and evolution, and when coupled with data supporting key roles for ZMAT2 in keratinocyte differentiation and pre-RNA splicing argue that this gene is worthy of further study.

The Mitochondrial Genome of Eleusine indica and Characterization of Gene Content Within Poaceae

Plant mitochondrial (mt) genome assembly provides baseline data on size, structure and gene content, but resolving the sequence of these large and complex organelle genomes remains challenging due to fragmentation, frequent recombination, and transfers of DNA from neighboring plastids. The mitochondrial genome for Eleusine indica (Poaceae: goosegrass) is comprehensibly analyzed here, providing key reference data for an economically significant invasive species that is also the maternal parent of the allotetraploid crop Finger millet (Eleusine coracana). The assembled E. indica genome contains 33 protein coding genes, 6 rRNA subunits, 24 tRNA, 8 large repetitive regions 15 kb of transposable elements across a total of 520,691 bp. Evidence of RNA editing and loss of rpl2, rpl5, rps14, rps11, sdh4 and sdh3 genes is evaluated in the context of an updated survey of mt genomic gene content across the grasses through an analysis of available publicly available data. Hypothesized patterns of Poaceae mt gene loss are examined in a phylogenetic context to clarify timing, showing that rpl2 was transferred to the nucleus from the mitochondrion prior to the origin of the PACMAD clade.

Genomic data do not support comb jellies as the sister group to all other animals

Understanding how complex traits, such as epithelia, nervous systems, muscles, or guts, originated depends on a well-supported hypothesis about the phylogenetic relationships among major animal lineages. Traditionally, sponges (Porifera) have been interpreted as the sister group to the remaining animals, a hypothesis consistent with the conventional view that the last common animal ancestor was relatively simple and more complex body plans arose later in evolution. However, this premise has recently been challenged by analyses of the genomes of comb jellies (Ctenophora), which, instead, found ctenophores as the sister group to the remaining animals (the “Ctenophora-sister” hypothesis). Because ctenophores are morphologically complex predators with true epithelia, nervous systems, muscles, and guts, this scenario implies these traits were either present in the last common ancestor of all animals and were lost secondarily in sponges and placozoans (Trichoplax) or, alternatively, evolved convergently in comb jellies. Here, we analyze representative datasets from recent studies supporting Ctenophora-sister, including genome-scale alignments of concatenated protein sequences, as well as a genomic gene content dataset. We found no support for Ctenophora-sister and conclude it is an artifact resulting from inadequate methodology, especially the use of simplistic evolutionary models and inappropriate choice of species to root the metazoan tree. Our results reinforce a traditional scenario for the evolution of complexity in animals, and indicate that inferences about the evolution of Metazoa based on the Ctenophora-sister hypothesis are not supported by the currently available data.