Genome-wide identification and expression analysis of the cucumber PYL gene family

Abscisic acid (ABA) is a very important hormone in plants. It regulates growth and development of plants and plays an important role in biotic and abiotic stresses. The Pyrabactin resistance 1-like (PYR/PYL) proteins play a central role in ABA signal transduction pathways. The working system of PYL genes in cucumber, an important economical vegetable (Cucumis sativus L.), has not been fully studied yet. Through bioinformatics, a total of 14 individual PYL genes were identified in Chinese long ‘9930’ cucumber. Fourteen PYL genes were distributed on six chromosomes of cucumber, and their encoded proteins predicted to be distributed in cytoplasm and nucleus. Based on the phylogenetic analysis, the PYL genes of cucumber, Arabidopsis, rice, apple, Brachypodium distachyon and soybeancould be classified into three groups. Genetic structures and conserved domains analysis revealed that CsPYL genes in the same group have similar exons and conserved domains. By predicting cis-elements in the promoters, we found that all CsPYL members contained hormone and stress-related elements. Additionally, the expression patterns of CsPYL genes were specific in tissues. Finally, we further examined the expression of 14 CsPYL genes under ABA, PEG, salt stress. The qRT-PCR results showed that most PYL gene expression levels were up-regulated. Furthermore, with different treatments about 3h, the relative expression of PYL8 was up-regulated and more than 20 times higher than 0h. It indicated that this gene may play an important role in abiotic stress.

4.1N-Mediated Interactions and Functions in Nerve System and Cancer

Scaffolding protein 4.1N is a neuron-enriched 4.1 homologue. 4.1N contains three conserved domains, including the N-terminal 4.1-ezrin-radixin-moesin (FERM) domain, internal spectrin–actin–binding (SAB) domain, and C-terminal domain (CTD). Interspersed between the three domains are nonconserved domains, including U1, U2, and U3. The role of 4.1N was first reported in the nerve system. Then, extensive studies reported the role of 4.1N in cancers and other diseases. 4.1N performs numerous vital functions in signaling transduction by interacting, locating, supporting, and coordinating different partners and is involved in the molecular pathogenesis of various diseases. In this review, recent studies on the interactions between 4.1N and its contactors (including the α7AChr, IP3R1, GluR1/4, GluK1/2/3, mGluR8, KCC2, D2/3Rs, CASK, NuMA, PIKE, IP6K2, CAM 1/3, βII spectrin, flotillin-1, pp1, and 14-3-3) and the 4.1N-related biological functions in the nerve system and cancers are specifically and comprehensively discussed. This review provides critical detailed mechanistic insights into the role of 4.1N in disease relationships.

Bispezifische Antikörper: Hoffnungsträger in der Krebsimmuntherapie

Nearly seventy years have passed since the first attempts to fuse the antibodies, „magic bullets“ with exquisite target specificity, into multispecific agents that can connect a targeted cell with an effector immune cell. Such efforts have triggered a plethora of engineering advancements to optimize the antigen engagement. Even the most conserved domains of the antibody molecule have been modified to achieve two unique chains pairing, or with an introduction of novel antigen binding sites.

Genome-wide identification and expression analysis of the growth regulating factor (GRF) family in Jatropha curcas

GRF genes have been confirmed to have important regulatory functions in plant growth, development and response to abiotic stress. Although the genome of Jatropha curcas is sequenced, knowledge about the identification of the species’ GRF genes and their expression patterns is still lacking. In this study, we characterized the 10 JcGRF genes. A detailed investigation into the physic nut GRF gene family is performed, including analysis of the exon-intron structure, conserved domains, conserved motifs, phylogeny, chromosomal locations, potential small RNA targets and expression profiles under both normal growth and abiotic stress conditions. Phylogenetic analysis indicated that the 10 JcGRF genes were classified into five groups corresponding to group I, II, III, IV and V. The analysis of conserved domains showed that the motifs of JcGRF genes were highly conserved in Jatropha curcas. Expression analysis based on RNA-seq and qRT-PCR showed that almost all JcGRF genes had the highest expression in seeds, but very low expression was detected in the non-seed tissues tested, and four JcGRF genes responded to at least one abiotic stress at at least one treatment point. Our research will provide an important scientific basis for further research on the potential functions of JcGRF genes in Jatropha curcas growth and development, and response to abiotic stress, and will eventually provide candidate genes for the breeding of Jatropha curcas.

COVID-19: CRISPR/Cas-like System of nsp3 Promotes the Mutant Recombination and Drug Resistance

<p>Patients with novel coronavirus pneumonia usually suffer from bacterial and fungal infections, and the drug resistance problem caused by the pandemic is becoming more and more serious. Simultaneously, the SARS-COV-2 virus has a rapid mutation phenomenon, and somegene coding regions by mutation and recombination may be related to the drug resistance of the virus. Therefore, studying the relationship between the co-infection of bacteria and fungi and the evolution of SARS-COV-2 has important guiding significance for preventing a pandemic. We found that the SARS-COV-2 virus's nsp3 protein had a CRISPR/Cas 9 (II-B)-like function by searching for conserved domains. The system could target and edit the negative-strand RNA of SARS-COV-2. We speculated that the crRNA (CRISPR RNA) produced by the CRISPR/Cas system of Pseudomonas aeruginosa carried the genetic information of the conserved domains of bacteriophages and Pseudomonas, including drug resistance. After the phage lysed the Pseudomonas, the crRNA was released and attached to the fungal spores, and then invaded the patient's cells along with the spores or hyphae. nsp3 synthesized and assembled 4Fe-4S, iron-containing molecules bound to the cas4 domain, in the mitochondria of phagocytes. The iron came from hemoglobin attacked by the SARS-COV-2 virus protein. The nsp3 protein bound the crRNA in the phagocytic cytoplasm. It targeted the negative-strand RNA of SARS-COV-2, inserting conserved domain gene fragments into the negative-strand RNA through editing and splicing. Since the Cas protein had no codon checking function, the cutting and splicing would destroy the protein-coding information in the original RNA coding region, causing mutation and recombination of the SARS-COV-2 virus genome. If crRNA carried the drug resistance gene fragments of bacteria or phage, SARS-COV-2 would have similar drug resistance. Because of the growing problem of drug resistance in COVID-19 patients, we should pay attention to preventing fungi and bacteria co-infection. Avoid the CRISPR/Cas-like system of the novel coronavirus to cause rapid mutation and recombination and increased the drug resistance problem of SARS-COV-2.</p>

COVID-19: CRISPR/Cas-like System of nsp3 Promotes the Mutant Recombination and Drug Resistance

<p>Patients with novel coronavirus pneumonia usually suffer from bacterial and fungal infections, and the drug resistance problem caused by the pandemic is becoming more and more serious. Simultaneously, the SARS-COV-2 virus has a rapid mutation phenomenon, and somegene coding regions by mutation and recombination may be related to the drug resistance of the virus. Therefore, studying the relationship between the co-infection of bacteria and fungi and the evolution of SARS-COV-2 has important guiding significance for preventing a pandemic. We found that the SARS-COV-2 virus's nsp3 protein had a CRISPR/Cas 9 (II-B)-like function by searching for conserved domains. The system could target and edit the negative-strand RNA of SARS-COV-2. We speculated that the crRNA (CRISPR RNA) produced by the CRISPR/Cas system of Pseudomonas aeruginosa carried the genetic information of the conserved domains of bacteriophages and Pseudomonas, including drug resistance. After the phage lysed the Pseudomonas, the crRNA was released and attached to the fungal spores, and then invaded the patient's cells along with the spores or hyphae. nsp3 synthesized and assembled 4Fe-4S, iron-containing molecules bound to the cas4 domain, in the mitochondria of phagocytes. The iron came from hemoglobin attacked by the SARS-COV-2 virus protein. The nsp3 protein bound the crRNA in the phagocytic cytoplasm. It targeted the negative-strand RNA of SARS-COV-2, inserting conserved domain gene fragments into the negative-strand RNA through editing and splicing. Since the Cas protein had no codon checking function, the cutting and splicing would destroy the protein-coding information in the original RNA coding region, causing mutation and recombination of the SARS-COV-2 virus genome. If crRNA carried the drug resistance gene fragments of bacteria or phage, SARS-COV-2 would have similar drug resistance. Because of the growing problem of drug resistance in COVID-19 patients, we should pay attention to preventing fungi and bacteria co-infection. Avoid the CRISPR/Cas-like system of the novel coronavirus to cause rapid mutation and recombination and increased the drug resistance problem of SARS-COV-2.</p>

Sequence and phylogenetic analysis revealed structurally conserved domains and motifs in lincRNA-p21

Long Intergenic Non-coding RNAs (lincRNAs) are the largest class of long non-coding RNAs in the eukaryotes, which originate from the intergenic regions of the genome. A ~4kb long lincRNA-p21 is derived from a transcription unit next to the p21/Cdkn1a gene locus. LincRNA-p21 plays key regulatory roles in p53 dependent transcriptional repression and translational repression through its physical association with proteins such as hnRNP-K and HuR. It is also involved in the aberrant gene expression in different cancers. However, detailed information on its structure, recognition, and trans-regulation by proteins is not well known. In this study, we have carried out a complete gene analysis and annotation of lincRNA-p21. This analysis showed that lincRNA-p21 is highly conserved in primates, and its conservation drops significantly in lower organisms. Furthermore, our analysis has revealed two structurally conserved domains in the 5’ and 3’ terminal regions of lincRNA-p21. Phylogenetic analysis has revealed discrete evolutionary dynamics in these conserved domains for orthologous sequences of lincRNA-p21, which have evolved slowly across primates compared to other mammals. Using Infernal based covariance analysis, we have computed the secondary structures of these domains. The secondary structures were further validated by energy minimization criteria for individual orthologous sequences as well as the full-length human lincRNA-p21. In summary, this analysis has led to the identification of sequence and structural motifs in the conserved fragments, indicating the functional importance for these regions.

Identification of the conserved domains of ADP-Glucose Pyrophosphorylase (AGPase) protein in sweetpotato (Ipomoea batatas (L.) Lam.) and its two wild relatives

The conserved domains are defined as recurring units in molecular evolution, which are commonly used to interpret the molecular function and biochemical structure of proteins. The AGPase amino acid sequences of three species from the Ipomoea genus were identified to investigate their physicochemical and biochemical characteristics. The molecular weights (MW), isoelectric point (pI), instability index (II), and grand average of hydropathy (GRAVY) showed considerable differences in each plant. The aliphatic index (AI) values of sweetpotato AGPase proteins were higher in the small subunit than in the large subunit. The AGPase proteins from sweetpotato contain an LbH_G1P_AT_C domain in the C-terminal region and various domains (NTP_transferase, ADP_Glucose_PP, or Glyco_tranf_GTA) in the N-terminal region. On the other hand, most of its two relatives (I. trifida and I. triloba) only contain the NTP_transferase domain in the N-terminal region. These findings suggested that these conserved domains were species specificity and related to the subunit types of AGPase proteins. The study may enable research on the AGPase-related specific characteristics of sweetpotatoes, which do not exist in the other two species, such as starch metabolism and tuberization mechanism.

An updated census of the maize TIFY family

The TIFY gene family is a plant-specific gene family encoding a group of proteins characterized by its namesake, the conservative TIFY domain and members can be organized into four subfamilies: ZML, TIFY, PPD and JAZ (Jasmonate ZIM-domain protein) by presence of additional conserved domains. The TIFY gene family is intensively explored in several model and agriculturally important crop species and here, yet the composition of the TIFY family of maize has remained unresolved. This study increases the number of maize TIFY family members known by 40%, bringing the total to 47 including 38 JAZ, 5 TIFY, and 4 ZML genes. The majority of the newly identified genes were belonging to the JAZ subfamily, six of which had aberrant TIFY domains, suggesting loss JAZ-JAZ or JAZ-NINJA interactions. Six JAZ genes were found to have truncated Jas domain or an altered degron motif, suggesting resistance to classical JAZ degradation. In addition, seven membranes were found to have an LxLxL-type EAR motif which allows them to recruit TPL/TPP co-repressors directly without association to NINJA. Expression analysis revealed that ZmJAZ14 was specifically expressed in the seeds and ZmJAZ19 and 22 in the anthers, while the majority of other ZmJAZs were generally highly expressed across diverse tissue types. Additionally, ZmJAZ genes were highly responsive to wounding and JA treatment. This study provides a comprehensive update of the maize TIFY/JAZ gene family paving the way for functional, physiological, and ecological analysis.