Zinc Finger Motifs Research Articles

Comparative analysis of amino acid sequence level in plant GATA transcription factors

Transcription factors (TFs) are essential regulators of gene expression, influencing numerous biological processes such as development, growth, and cellular responses in plants. Among these, GATA TFs are distinguished by their highly conserved DNA-binding domain, characterized by a class IV zinc finger motif (CX2CX18-20CX2C). This study investigates the amino acid sequence patterns of 5,335 GATA TFs across 165 plant species sourced from the PlantTFDB database (http://planttfdb.gao-lab.org/), encompassing diverse taxonomic groups. Through comparative sequence analysis, I identify conserved domains and structural features that enhance the understanding functional roles, evolutionary conservation, and lineage-specific adaptations of GATA TFs. These findings provide valuable insights into the diversification and functional specialization of GATA TFs, with implications for improving stress tolerance and adaptability in crops. This study contributes to the broader knowledge of transcriptional regulation in plant biology.

Computer-aided rational design of a mRNA vaccine against Guanarito mammarenavirus.

Guanarito mammarenavirus (GTOV) is a highly pathogenic virus that leads to Venezuelan hemorrhagic fever (VHF). Despite being a severe disease, there are currently no commercially available drugs or vaccines for its prevention. Here we computationally formulated a mRNA vaccine construct (VC) from the genome of GTOV to produce immunity against its infections. Two proteins, namely zinc-finger motif protein (NP_899220.1), and nucleocapsid protein (NP_899211.1) were screened as potential candidates for downstream analysis. We determined the T and B cell epitopes of the candidate proteins. The resulting epitopes were analyzed, and the best epitopes were utilized in the formation of the peptide vaccine construct. The secondary and tertiary structures of the peptide construct were predicted and validated. Docking was conducted to check the binding energy of the designed peptide vaccine with the human immune receptors, namely TLR2 and TLR4. Our designed vaccine showed stable interactions with the HLA molecules, as verified through normal mode and MD simulation analysis. The immune simulation results indicated a positive immune response against the construct. A potentially stable mRNA vaccine was formulated by adding of sequences such as the Kozak, Goblin 5' UTR, tPA-signal peptide, MITD, 3' UTRs, and a poly(A) tail to the peptide vaccine construct. Lastly, the expression probability of the mRNA vaccine was confirmed in the expression system of E. coli strain K12. The designed vaccine showed the potential to elicit an immune response against the GTOV infection; however, experimental validation is recommended to verify the in-silico findings of this study.

Exome variant prioritization in a large cohort of hearing-impaired individuals indicates IKZF2 to be associated with non-syndromic hearing loss and guides future research of unsolved cases

Although more than 140 genes have been associated with non-syndromic hereditary hearing loss (HL), at least half of the cases remain unexplained in medical genetic testing. One reason is that pathogenic variants are located in ‘novel’ deafness genes. A variant prioritization approach was used to identify novel (candidate) genes for HL. Exome-wide sequencing data were assessed for subjects with presumed hereditary HL that remained unexplained in medical genetic testing by gene-panel analysis. Cases in group AD had presumed autosomal dominantly inherited HL (n = 124), and in group AR, presumed autosomal recessive HL (n = 337). Variants in known and candidate deafness genes were prioritized based on allele frequencies and predicted effects. Selected variants were tested for their co-segregation with HL. Two cases were solved by variants in recently identified deafness genes (ABHD12, TRRAP). Variant prioritization also revealed potentially causative variants in candidate genes associated with recessive and X-linked HL. Importantly, missense variants in IKZF2 were found to co-segregate with dominantly inherited non-syndromic HL in three families. These variants specifically affected Zn2+-coordinating cysteine or histidine residues of the zinc finger motifs 2 and 3 of the encoded protein Helios. This finding indicates a complex genotype–phenotype correlation for IKZF2 defects, as this gene was previously associated with non-syndromic dysfunction of the immune system and ICHAD syndrome, including HL. The designed strategy for variant prioritization revealed that IKZF2 variants can underlie non-syndromic HL. The large number of candidate genes for HL and variants therein stress the importance of inclusion of family members for variant prioritization.

KLF14 directly downregulates the expression of GPX4 to exert antitumor effects by promoting ferroptosis in cervical cancer

BackgroundCervical cancer is the fourth leading cause of cancer-related death among women worldwide, and effective therapeutic strategies for its treatment are limited. Recent studies have indicated that ferroptosis, a form of regulated cell death, is a promising therapeutic strategy. KLF14 has been shown to regulate both cell proliferation and apoptosis in cervical cancer. However, its role in modulating lipid peroxidation and ferroptosis remains largely unexplored and enigmatic.MethodsSiHa and HeLa cells were transduced with lentiviral vectors to overexpress KLF14. Protein levels were analyzed via western blotting and immunohistochemistry (IHC). LDH assays, calcein-AM/propidium iodide (PI) staining, and generation of cell growth curves using a real-time cell analysis (RTCA) system were used to detect cell damage and proliferation. Cellular ROS, lipid ROS, transmission electron microscopy (TEM), and Fe2+ assays and a xenograft mouse model were used to measure the level of ferroptosis. Proteomics combined with bioinformatics methods was used to screen target genes regulated by KLF14, and CUT&Tag and dual-luciferase assays confirmed the repression of GPX4 by KLF14 via direct binding to its promoter.ResultsKLF14 is abnormally expressed in various tumors and downregulated in cervical cancer. Overexpression of KLF14 induced ferroptosis and inhibited cell proliferation in vitro as well as xenograft tumorigenicity in vivo. Mechanistic studies revealed that KLF14 binds to the promoter of GPX4, suppressing its transcriptional activity and thereby decreasing its expression, which contributes to the induction of ferroptosis. Truncation and point mutation analyses of the GPX4 promoter revealed multiple binding sites for KLF14 within the − 1000 bp to + 35 bp region, which are responsible for its inhibitory effect on GPX4 transcription. Additionally, deletion of the zinc finger motif in KLF14 abolished its inhibitory effect on GPX4 promoter activity and cell proliferation.ConclusionOur data revealed a previously unidentified function of KLF14 in promoting ferroptosis, which results in the suppression of cell proliferation. Mechanistically, we revealed a novel regulatory mechanism by which KLF14 targets GPX4. These findings suggest a novel strategy to induce ferroptosis through the targeting of KLF14 in human cervical cancer cells.

Members of WRKY Group III Transcription Factors Are Important in Mite Infestation in Strawberry (Fragaria × ananassa Duch.)

Strawberry is frequently attacked by mites, which directly affects the yield and quality of this fruit species. The WRKY Group III transcription factors (TFs) play an important role in plant tolerance to biotic sources of stress, such as pathogens and insect pests. In this study, six Group III WRKY TFs (FaWRKY25, FaWRKY31, FaWRKY32, FaWRKY43, FaWRKY44, and FaWRKY45) were identified in strawberry. A phylogenetic analysis showed that the six WRKY III TFs were divided into two clades and all had a conserved WRKYGQK domain and the C-X7-C-X23-H-T-C zinc finger motif. An interaction network analysis revealed that FaWRKY44 was co-expressing with FaWRKY25 and FaWRKY45. The expression patterns showed that the WRKY Group III genes responded to plant hormones and mite infestation in strawberry. To further verify the role of FaWRKY25 in plant resistance to mites, we cloned the FaWRKY25 gene and overexpressed it in transgenic plants. An in vivo subcellular localization analysis indicated that the FaWRKY25 protein was localized in the nucleus. Fewer mites were also detected on the wild-type plants than on FaWRKY25-overexpressing transgenic plants, suggesting that FaWRKY25 negatively regulates the resistance of strawberry to mites. The present study advances our understanding on a potential target that mites use to manipulate host plant defenses.

Genome-wide analysis of the WRKY gene family and their response to low-temperature stress in elephant grass.

Elephant grass (Cenchrus purpureus) is a perennial forage grass characterized by tall plants, high biomass and wide adaptability. Low-temperature stress severely limits elephant grass biomass and geographic distribution. WRKY is one of the largest families of plant-specific transcription factors and plays important roles in plant resistance to low-temperature. However, the understanding of the WRKY family in grasses is limited. In this study, we conducted a genome-wide characterization of WRKY proteins in elephant grass, including gene structure, phylogeny, expression, conserved motif organization, and functional annotation, to identify key CpWRKY candidates involved in cold tolerance. In this study, a total of 176 WRKY genes were identified in elephant grass. It was found that 172 were unevenly distributed across its 14 chromosomes, while the remaining 4 genes were not anchored to any chromosome. The genes were classified into three groups based on their WRKY conserved domains and zinc finger motifs. There were 12, 8, 19, 27, 12, 18 and 80 CpWRKYs belonging to group I, group IIa, group IIb, group IIc, group IId, group IIe and group III, respectively. We hypothesized that the ancient subgroup IIc WRKY gene is the ancestor of all WRKY genes in elephant grass. Most CpWRKYs in the same group have similar structure and motif composition. A total of 169 duplicate gene pairs were identified, suggesting that segmental duplication might have contributed to the expansion of the CpWRKY gene family. Ka/Ks analysis revealed that most of the CpWRKYs were subjected to purifying selection during the evolution. It was also found that six genes (CpWRKY51, CpWRKY81, CpWRKY100, CpWRKY101, CpWRKY140 and CpWRKY143) exhibited higher expression in roots compare to leaves, and were significantly induced by low temperature stress. Among them, CpWRKY81 had the highest expression under low-temperature stress, and its over-expression significantly enhanced the cold tolerance in yeast. In this study, we characterized WRKY genes in elephant grass and further investigated their physicochemical properties, evolution, and expression patterns under low-temperature stress. This research provides valuable resources for identifying key CpWRKY genes that contribute to cold tolerance in elephant grass.

Uncovering the profile of ubiquitination motif in catalytic proteins using sequence contextual features

Ubiquitin molecules modify their target protein by conjugating the amino group of lysine side chain, thereby regulating the activity and function of most intracellular proteins. However, within multiple lysine residues on a target protein, only particular residues can be modified by ubiquitin molecules. The occurrence of ubiquitination varies on different lysine residues. The ubiquitination of a lysine residue is ubiquitinated depends on the environment of amino acid sequences near the lysine residue; this sequence is called a motif. Although the interaction of motifs with ubiquitin molecules have been extensively studied, there have been no reports on the ubiquitination motifs. In the current study, 133 878 ubiquitinated peptide data from 27 762 proteins in 30 articles and the mUbiSiDa database in the past decade were collected and analyzed. A total of 208 motifs were found with a score above 6, covering most of the ubiquitination peptides. Of these, six motifs with higher scores and significant regularity were found to belong to zinc finger proteins and serine/threonine kinases, termed zinc finger and serine/threonine kinase motifs, respectively. Analysis on four zinc finger motifs revealed that the ubiquitination sites in zinc finger motifs, xxHxxxxxxE_K_xxxCxxCxxx and xxxKxxHxxx_K_xxxxxExxKx, were located between two zinc finger domains, while the ubiquitination sites in zinc finger motifs, xxxxxxxxCG_K_xFxxxxxxxx and CxxxxxxFxQ_K_xxxxxxxxxx were located within zinc chelation structure near one Cys residue. Different proteins contain different types and quantities of zinc finger motifs. The results of the 3D structure showed that the ubiquitination sites in motif CxxxxxxFxQ_K_xxxxxxxxxx were located in the ring structure of the zinc finger domain. This may affect the interaction between zinc finger domains and DNA. Meanwhile, the ubiquitination sites of the other three zinc finger motifs located outside the interaction structure between zinc finger domains and DNA may not serve to block interaction but degradation. The analysis of two serine/threonine kinase motifs revealed that some residues near the ubiquitination site in two serine/threonine kinase motifs were completely identical in different proteins; however, these conserved residues were completely different in different motifs, suggesting the varied function of the two motifs. Moreover, it was found that no protein simultaneously contains both serine/threonine kinase motifs. Although there were significant differences in the amino acid sequences of these motifs, their spatial structures were highly conserved. These results suggest that the regulatory functions of the two motifs may differ. This is because two motifs may be recognized by different ubiquitinases or deubiquitinases. Overall, these results suggest that the motifs of ubiquitination sites exhibit high regularity and special structural characteristics in different types of proteins. This study sheds light on the profile and regularity of ubiquitination motifs, promoting the prediction of the function, structure, and modified sites of ubiquitinated proteins.

Structure and Dynamics of the CCCH-Type Tandem Zinc Finger Domain of POS-1 and Implications for RNA Binding Specificity.

CCCH-type tandem zinc finger (TZF) motifs are found in many RNA-binding proteins involved in regulating mRNA stability, translation, and splicing. In Caenorhabditis elegans, several RNA-binding proteins that regulate embryonic development and cell fate determination contain CCCH TZF domains, including POS-1. Previous biochemical studies have shown that despite high levels of sequence conservation, POS-1 recognizes a broader set of RNA sequences compared to the human homologue tristetraprolin. However, the molecular basis of these differences remains unknown. In this study, we refined the consensus RNA sequence and determined the differing binding specificities of the two zinc fingers of POS-1. We also determined the solution structure and characterized the internal dynamics of the TZF domain of POS-1. From the structure, we identified unique features that define the RNA binding specificity of POS-1. We also observed that the TZF domain of POS-1 is in equilibrium between interconverting conformations. Transitions between these conformations require internal motions involving many residues with correlated dynamics in each ZF. We propose that the correlated dynamics are necessary to allow allosteric communication between the nucleotide-binding pockets observed in the N-terminal ZF. Our study shows that both the structure and conformational plasticity of POS-1 are important in ensuring recognition of its RNA binding targets.

Consensus QTL map deciphered genes and pathways regulating tolerance to post‐flowering diseases in maize

AbstractPost‐flowering diseases (PFDs), such as ear rot, stalk rot and smut, affect maize yield and quality by damaging the reproductive organs, stalks and seeds. We hypothesized that quantitative trait loci (QTL) associated with different PFDs colocalize and share similar defence mechanisms. Hence, to find a stable consensus meta‐QTL (MQTL) for single or multiple PFDs, MQTL analysis was performed. QTL conferring resistance to PFD reported in 31 independent studies were collated to develop a consensus map. As many as 49 MQTL conferring PFD resistance were projected using appropriate algorithms. Most MQTL regions encompass genes encoding a wide range of defence‐related proteins. MQTL1.1 and MQTL10.5 included QTL/genes for resistance to all PFDs, which supported our hypothesis. Candidate genes for PFDs in MQTL7.1 were associated with pathogenesis‐related 1 protein and mitogen‐activated protein kinase (MAPK) signalling. MQTL5.2 encompassed chalcone flavanone isomerase and cinnamoyl coenzyme A (CoA) reductase genes involved in flavonoid and phenylpropanoid biosynthesis, respectively. Furthermore, MQTL10.4 was found to harbour genes encoding E3 ubiquitin ligase, WRKY‐TF11, calcium‐binding domains and zinc finger motifs. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analysis reiterated the role of genes within MQTL7.1 in the MAPK signalling pathway, phytohormone signal transduction and plant–pathogen interaction. Hence, we propose that these genes are potential candidates for PFD resistance. Furthermore, 75% of the genes within the MQTL showed orthology with sorghum and rice, indicating that these genes were conserved across species. The role of 27 MQTL, including the six most significant MQTL, was confirmed with reported genome‐wide association study (GWAS) results. Thus, the hotspots associated with PFDs identified in our study could be reliably used in marker‐assisted breeding for PFD resistance.

INDETERMINATE DOMAIN Transcription Factors in Crops: Plant Architecture, Disease Resistance, Stress Response, Flowering, and More

INDETERMINATE DOMAIN (IDD) genes encode plant-specific transcription factors containing a conserved IDD domain with four zinc finger motifs. Previous studies on Arabidopsis IDDs (AtIDDs) have demonstrated that these genes play roles in diverse physiological and developmental processes, including plant architecture, seed and root development, flowering, stress responses, and hormone signaling. Recent studies have revealed important functions of IDDs from rice and maize, especially in regulating leaf differentiation, which is related to the evolution of C4 leaves from C3 leaves. Moreover, IDDs in crops are involved in the regulation of agriculturally important traits, including disease and stress resistance, seed development, and flowering. Thus, IDDs are valuable targets for breeding manipulation. This review explores the role of IDDs in plant development, environmental responses, and evolution, which provides idea for agricultural application.

Identification of WRKY transcription factors in Rosa chinensis and analysis of their expression response to alkali stress response

Breeding abiotic stress-tolerant varieties of Rosa chinensis is a paramount goal in horticulture. WRKY transcription factors, pivotal in plant responses to diverse stressors, offer potential targets for enhancing stress resilience in R. chinensis. Using bioinformatics and genomic data, we identified RcWRKY transcription factor genes, characterised their chromosomal distribution, phylogenetic relationships, structural attributes, collinearity, and expression patterns in response to saline stress. Leveraging bidirectional database searches, we pinpointed 66 RcWRKY genes, categorised into three groups. All except RcWRKY60 encoded DNA Binding Domain and Zinc Finger Motif regions of the WRKY domain. Expansion of the RcWRKY gene family was propelled by 19 segmental, and 2 tandem, duplications. We unveiled 41 and 15 RcWRKY genes corresponding to 50 AtWRKY and 17 OsWRKY orthologs respectively, indicating postdivergence expansion. Expression analyses under alkaline stress pinpointed significant alterations in 54 RcWRKY genes. Integration of functional roles from their Arabidopsis orthologs and cis-acting elements within their promoters, along with quantitative reverse transcription PCR validation, underscored the importance of RcWRKY27 and 29 in R. chinensis’ alkaline stress response. These findings offer insights into the biological roles of RcWRKY transcription factors, as well as the regulatory dynamics governing R. chinensis’ growth, development, and stress resilience.

Sex-Specific ADNP/NAP (Davunetide) Regulation of Cocaine-Induced Plasticity

Cocaine use disorder (CUD) is a chronic neuropsychiatric disorder estimated to effect 1–3% of the population. Activity-dependent neuroprotective protein (ADNP) is essential for brain development and functioning, shown to be protective in fetal alcohol syndrome and to regulate alcohol consumption in adult mice. The goal of this study was to characterize the role of ADNP, and its active peptide NAP (NAPVSIPQ), which is also known as davunetide (investigational drug) in mediating cocaine-induced neuroadaptations. Real time PCR was used to test levels of Adnp and Adnp2 in the nucleus accumbens (NAc), ventral tegmental area (VTA), and dorsal hippocampus (DH) of cocaine-treated mice (15 mg/kg). Adnp heterozygous (Adnp+/−)and wild-type (Adnp+/−) mice were further tagged with excitatory neuronal membrane-expressing green fluorescent protein (GFP) that allowed for in vivo synaptic quantification. The mice were treated with cocaine (5 injections; 15 mg/kg once every other day) with or without NAP daily injections (0.4 µg/0.1 ml) and sacrificed following the last treatment. We analyzed hippocampal CA1 pyramidal cells from 3D confocal images using the Imaris x64.8.1.2 (Oxford Instruments) software to measure changes in dendritic spine density and morphology. In silico ADNP/NAP/cocaine structural modeling was performed as before. Cocaine decreased Adnp and Adnp2 expression 2 h after injection in the NAc and VTA of male mice, with mRNA levels returning to baseline levels after 24 h. Cocaine further reduced hippocampal spine density, particularly synaptically weaker immature thin and stubby spines, in male Adnp+/+) mice while increasing synaptically stronger mature (mushroom) spines in Adnp+/−) male mice and thin and stubby spines in females. Lastly, we showed that cocaine interacts with ADNP on a zinc finger domain identical to ketamine and adjacent to a NAP-zinc finger interaction site. Our results implicate ADNP in cocaine abuse, further placing the ADNP gene as a key regulator in neuropsychiatric disorders. Ketamine/cocaine and NAP treatment may be interchangeable to some degree, implicating an interaction with adjacent zinc finger motifs on ADNP and suggestive of a potential sex-dependent, non-addictive NAP treatment for CUD.

Involvement of PG1037 in the repair of 8-oxo-7,8-dihydroguanine caused by oxidative stress in Porphyromonas gingivalis.

The PG1037 gene is part of the uvrA-PG1037-pcrA operon in Porphyromonas gingivalis. It encodes for a protein of unknown function upregulated under hydrogen peroxide (H2O2)-induced oxidative stress. Bioinformatic analysis shows that PG1037 has a zinc-finger motif, two peroxidase motifs, and one cytidylate kinase domain. The aim of this study is to characterize further the role of the PG1037 recombinant protein in the unique 8-oxoG repair system in P. gingivalis. PG1037 recombinant proteins with deletions in the zinc-finger or peroxidase motifs were created. Electrophoretic mobility shift assays were used to evaluate the ability of the recombinant proteins to bind 8-oxoG-containing oligonucleotides. Zinc binding, peroxidase, and Fenton reaction assays were used to assess the functional roles of the rPG1037 protein. A bacterial adenylate cyclase two-bride assay was used to identify the partner protein of PG1037 in the repair of 8-oxoG. The recombinant PG1037 (rPG1037) protein carrying an N-terminal His-tag demonstrated an ability to recognize and bind 8-oxoG-containing oligonucleotide. In contrast to the wild-type rPG1037 protein, the zinc-finger motif deletion resulted in the loss of zinc and 8-oxoG binding activities. A deletion of the peroxidase motif-1 showed a decrease in peroxidase activity. Using a bacterial adenylate cyclase two-hybrid system, there was no observed protein-protein interaction of PG1037 with UvrA (PG1036), PcrA (PG1038), or mismatch repair system proteins. Taken together, the results show that PG1037 is an important member of a novel mechanism that recognizes and repairs oxidative stress-induced DNA damage in P. gingivalis.

Arabidopsis Dph4 is an Hsp70 Cochaperone with Iron-Binding Properties.

J-domain proteins (JDPs) are obligate cochaperones of Hsp70s with a wide range of functions in protein homeostasis. Although the J-domain is required for the stimulation of Hsp70s ATPase activity, the functional specificity of JDPs is governed by domains or regions other than the J-domain. Jjj3/Dph4, a class III JDP, is required for diphthamide (DPH) biosynthesis in eukaryotes, including yeast and mammals. Dph4 has a conserved N-terminal J-domain and an uncharacterized C-terminal domain containing a signature CSL zinc finger motif. Previously, we showed that the Dph4 ortholog in Arabidopsis thaliana (atDjC13/AtJjj3/AtDph4) could restore DPH biosynthesis in yeast jjj3Δ mutant in a J-domain-dependent manner. Here, we characterize the C-terminal CSL motif of AtDph4 using yeast genetic and biochemical approaches. The CSL motif of AtDph4 is essential for DPH biosynthesis, and like human Dph4, AtDph4 showed distinct iron-binding activity, which is not present in its yeast counterpart. ScDph4 and AtDph4 proteins exhibit distinct iron-binding capabilities, as evidenced by UV-vis spectrophotometry, SEM-EDS (energy-dispersive spectroscopy function on the scanning electron microscope) and electron paramagnetic resonance (EPR) spectra analyses. Collectively, our data suggests that beyond their role as an Hsp70 cochaperone, Dph4 homologues in complex eukaryotes may have iron-binding abilities, indicating a potential role in iron-sulfur cluster assembly and iron homeostasis.

Zinc finger-inspired peptide-metal-phenolic nanointerface enhances bone-implant integration under bacterial infection microenvironment through immune modulation and osteogenesis promotion

Orthopedic and dental implantations under bacterial infection microenvironment face significant challenges in achieving high-quality bone-implant integration. Designing implant coatings that incorporate both immune defense and anti-inflammation is difficult in conventional single-functional coatings. We introduce a multifunctional nanointerface using a zinc finger-inspired peptide-metal-phenolic nanocoating, designed to enhance implant osseointegration under such conditions. Abaloparatide (ABL), a second-generation anabolic drug for treating osteoporosis, can be integrated into the design of a zinc-phenolic network constructed on the implant surface (ABL@ZnTA). Importantly, the phenolic-coordinated Zn2+ ions in ABL@ZnTA can act as zinc finger motif to co-stabilize the configuration of ABL through multiple molecular interactions, enabling high bioactivity, high loading capacity (1.36 times), and long-term release (>7 days) of ABL. Our results showed that ABL@ZnTA can modulate macrophage polarization from the pro-inflammatory M1 towards the anti-inflammatory M2 phenotype, promoting immune osteogenesis with increased OCN, ALP, and SOD 1 expression. Furthermore, the ABL@ZnTA significantly reduces inflammatory fibrous tissue encapsulation and enhances the long-term stability of the implants, indicated by enhanced binding strength (6 times) and functional connectivity (1.5−3 times) in the rat bone defect model infected by S. aureus. Overall, our research offers a nano-enabled synergistic strategy that balances infection defense and osteogenesis promotion in orthopedic and dental implantations.

Molecular characterization of the SP3a gene, a negative regulator of viral infection in the orange-spotted grouper, Epinephelus coioides

SP3 (specificity protein 3) is a transcription factor characterized by three conserved Cys2His2 zinc finger motifs that exert a transregulatory effect by binding to GC boxes, either upregulating or downregulating multiple genes or by co-regulating gene expression in coordination with other proteins. SP3 potentially regulates a series of processes, such as the cell cycle, growth, metabolic pathways, and apoptosis, and plays an important role in antiviral effect. The function of sp3 in fish is poorly understood. In this study, the Sp3a open reading frame was cloned from the orange-spotted grouper, Epinephelus coioides. The full-length open reading frame of Sp3a was 2034 bp, encoding 677 amino acids, with a predicted molecular weight of 72.34 kDa and an isoelectric point of 5.05. Phylogenetically, Sp3a in Epinephelus coioides was the most closely related to Sp3a in the Malabar grouper, Epinephelus malabaricus. RT-qPCR revealed ubiquitous expression of Sp3a in all examined grouper tissues, with no significant differences in expression levels among tissues. A eukaryotic expression vector, pEGFP-Sp3a, was constructed and transfected into grouper spleen (GS) cells. Subcellular localization of Sp3a was observed using an inverted fluorescence microscope. When Spa3 was overexpressed in GS cells, the expression of orange-spotted grouper nerve necrosis virus (RGNNV) genes (CP and RdRp) decreased significantly, indicating that Sp3a significantly inhibited RGNNV replication. siRNA inhibition of Sp3a accelerated the intracellular replication of RGNNV, implying the antiviral effect of Sp3a. Conclusively, our findings contribute to further research on the antiviral capabilities of Sp3a in grouper and other fish. Therefore, our research has potential implications on the development of the aquaculture industry.

Mining GATA Transcription Factor Encoding Genes in The Cocoa Tree (<i>Theobroma cacao</i> L.) Suggests Their Potential Roles in Embryo Development and Biotic Stress Response

GATA transcription factors (TFs) are widely recognized as significant regulators, characterized by a DNA-binding domain that consists of a type IV zinc finger motif. This TF family has been widely investigated in numerous higher plant species. The purpose of the present work was to comprehensively analyze the GATA TF in cocoa plant (Theobroma cacao L.) by using various bioinformatics tools. As a result, a total of 24 members of the GATA TFs have been identified and annotated in the assembly of the cocoa plant. According to phylogenetic analysis, these TcGATA proteins were classified into four distinct groups, including groups I (10 members), II (seven members), III (five members), and IV (two members). Next, our investigation indicated that the TcGATA proteins in different groups exhibited a high variation in their physic-chemical features due to their different protein lengths, gene structures, and conserved motif distributions, whereas the TcGATA proteins in the same clade might share the common conserved motifs. Additionally, the gene duplication of the TcGATA genes in the cocoa plant was also investigated. Of our interest, the relative expression levels of the TcGATA genes were investigated according to available transcriptome databases. The results exhibited differential expression patterns of all TcGATA genes in various developmental stages of zygotic and somatic embryogenesis, indicating that these TcGATA genes divergently function during various developmental stages of the zygotic and somatic embryos. Moreover, TcGATA genes were differently expressed under Phytophthora megakarya treatment across different points of treatment and cocoa varieties. To sum up, our findings could provide a basis for a further deep understanding of the GATAs in the cocoa plant.

Structural and functional characterization of cyclic pyrimidine-regulated anti-phage system

3’,5’-cyclic uridine monophosphate (cUMP) and 3’,5’-cyclic cytidine monophosphate (cCMP) have been established as bacterial second messengers in the phage defense system, named pyrimidine cyclase system for anti-phage resistance (Pycsar). This system consists of a pyrimidine cyclase and a cyclic pyrimidine receptor protein. However, the molecular mechanism underlying cyclic pyrimidine synthesis and recognition remains unclear. Herein, we determine the crystal structures of a uridylate cyclase and a cytidylate cyclase, revealing the conserved residues for cUMP and cCMP production, respectively. In addition, a distinct zinc-finger motif of the uridylate cyclase is identified to confer substantial resistance against phage infections. Furthermore, structural characterization of cUMP receptor protein PycTIR provides clear picture of specific cUMP recognition and identifies a conserved N-terminal extension that mediates PycTIR oligomerization and activation. Overall, our results contribute to the understanding of cyclic pyrimidine-mediated bacterial defense.

The assembly-defective phenotype of an FIV Gag polyprotein containing the SIV nucleocapsid zinc finger motifs is reversed by including the SIV SP2 domain in the chimeric protein

To gain insight into the functional relationship between the nucleocapsid (NC) domains of the Gag polyproteins of feline and simian immunodeficiency viruses, FIV and SIV, respectively, we generated two FIV Gag chimeric proteins containing different SIV NC and gag sequences. A chimeric FIV Gag protein (NC1) containing the SIV two zinc fingers motifs was incapable of assembling into virus-like particles. By contrast, another Gag chimera (NC2) differing from NC1 by the replacement of the C-terminal region of the FIV NC with SIV SP2 produced particles as efficiently as wild-type FIV Gag. Of note, when the chimeric NC2 Gag polyprotein was expressed in the context of the proviral DNA in feline CrFK cells, wild-type levels of virions were produced which encapsidated 50% of genomic RNA when compared to the wild-type virus.

A loss-of-function variant in KLF4 affecting zinc finger motifs causes progressive symmetric erythrokeratodermia.

We identified a novel de novo variant (c.1234C > A, p.His412Asn) in KLF4, which is located within the first zinc finger motifs of KLF4, in a patient with progressive symmetric erythrokeratodermia. By dual-luciferase reporter assay, quantitative reverse transcriptase-polymerase chain reaction and immunofluorescence, we demonstrated that the KLF4 variant is a loss-of-function mutation, and the expression of SLURP1 and DSG1, both of which are transcriptionally regulated by KLF4, was downregulated.