Protein Function Research Articles

The variegated canalized-1 tomato mutant is linked to photosystem assembly

The recently described canal-1 tomato mutant, which has a variegated leaf phenotype, has been shown to affect canalization of yield. The corresponding protein is orthologous to AtSCO2 -SNOWY COTYLEDON2, which has suggested roles in thylakoid biogenesis. Here we characterize the canal-1 mutant through a multi-omics approach, by comparing mutant to wild-type tissues. While white canal-1 leaves are devoid of chlorophyll, green leaves of the mutant appear wild-type-like, despite an impaired protein function. Transcriptomic data suggest that green mutant leaves compensate for this impaired protein function by upregulation of transcription of photosystem assembly and photosystem component genes, thereby allowing adequate photosystem establishment, which is reflected in their wild-type-like proteome. White canal-1 leaves, however, likely fail to reach a certain threshold enabling this overcompensation, and plastids get trapped in an undeveloped state, while additionally suffering from high light stress, indicated by the overexpression of ELIP homolog genes. The metabolic profile of white and to a lesser degree also green tissues revealed upregulation of amino acid levels, that was at least partially mediated by transcriptional and proteomic upregulation. These combined changes are indicative of a stress response and suggest that white tissues behave as carbon sinks. In summary, our work demonstrates the relevance of the SCO2 protein in both photosystem assembly and as a consequence in the canalization of yield.

ClassIIb histone deacetylase participates in perioperative neurocognitive disorders in elderly mice via HSP90/GR signaling pathway.

Multiple factors contribute to the development of perioperative neurocognitive disorders (PND). This study was designed to investigate whether Histone Deacetylase 6 (HDAC6) was involved in the formation of postoperative cognitive dysfunction in elderly mice by regulating the degree of acetylation of heat shock protein (HSP90) and related protein functions and quantities. C57BL/6J male mice were randomly divided into six groups: control naive (group Control), anesthesia (group Anesthesia), splenectomy surgery (group Surgery), splenectomy surgery plus dissolvent (group Vehicles), splenectomy surgery plus the inhibitor ACY-1215 (group Ricolinostat), and splenectomy surgery plus the inhibitor RU-486(group Mifepristone). After the mice were trained for Morris Water Maze (MWM) test for five days, anesthesia and operational surgery were carried out the following day. Cognitive function was assessed on the 1st, 3rd and 7th days post-surgery. The hippocampi were harvested on days 1, 3, and 7 post-surgeries for Western blots and ELISA assays. Mice with the splenectomy surgery displayed the activation of the hypothalamic-pituitary-adrenal axis (HPA-axis), marked an increase in adrenocorticotropic hormone (ACTH), glucocorticoid, mineralocorticoid at the molecular level and impaired spatial memory in the MWM test. The hippocampus of surgical groups showed a decrease in acetylated HSP90, a rise in glucocorticoid receptor (GR)-HSP90 association, and an increase in GR phosphorylation and translocation. HDAC6 was increased after the surgical treated. Using two specific inhibitors, HDAC6 inhibitor Ricolinostat (ACY-1215) and GR inhibitor Mifepristone (RU-486), can partially mitigate the effects caused by surgical operation. Abdominal surgery may impair hippocampal spatial memory, possibly through the HDAC6-triggered increase in the function of HSP90, consequently strengthening the negative role of steroids in cognitive function. Targeting HDAC6- HSP90/GR signaling may provide a potential avenue for the treatment of the impairment of cognitive function after surgery.

Site-specific O-GlcNAcylation of progesterone receptor (PR) supports PR attenuation of interferon stimulated genes (ISGs) and tumor growth in breast cancer

Hormone receptor (HR) positive breast cancer, defined by expression of estrogen (ER) and/or progesterone (PR) receptor expression, is the most commonly diagnosed type of breast cancer. PR alters the transcriptional landscape to support tumor growth in concert with or independent of ER. Thus, understanding the mechanisms regulating PR function are critical to developing new strategies to treat HR+ breast cancer. O-GlcNAc is a post-translational modification responsible for nutrient sensing that modulates protein function. Although PR is heavily post-translationally modified, through phosphorylation and O-GlcNAcylation, specific sites of O-GlcNAcylation on PR and how they regulate PR action, have not been investigated. Using established PR-expressing breast cancer cell lines, we mapped several sites of O-GlcNAcylation on PR. RNA-sequencing after PR O-GlcNAc site mutagenesis revealed site-specific O-GlcNAcylation of PR is critical for ligand-independent suppression of interferon signaling, a regulatory function of PR in breast cancer. Furthermore, O-GlcNAcylation of PR enhances PR-driven tumor growth in vivo. We have delineated one contributing mechanism to PR function in breast cancer that impacts tumor growth, and provided additional insight into the mechanism through which PR attenuates interferon signaling.

Deep metabolic phenotyping of humans with protein-altering variants in TM6SF2 using a genome-first approach

Background & AimAn unbiased genome-first approach can expand the molecular understanding of specific genes in disease-agnostic biobanks for deeper phenotyping. TM6SF2 represents a good candidate for this approach due to its known association with steatotic liver disease (SLD). MethodsWe screened participants with whole-exome sequences in the Penn Medicine Biobank (N>40,000) and the UK Biobank (UKB, N>200,000) for protein-altering variants in TM6SF2 and evaluated their association with liver phenotypes and clinical outcomes. ResultsThree missense variants in TM6SF2 (E167K, L156P, P216L) were associated with an increased risk of clinically-diagnosed and imaging-proven steatosis, independent of PNPLA3 I48M risk allele and hepatitis B/C (p<0.001). E167K homozygotes had significantly increased risk of SLD (OR:5.38, p<0.001), steatohepatitis (OR:5.76, p<0.05) and hepatocellular carcinoma (OR:11.22, p<0.0001) whilst nominal risk of steatohepatitis were present in L156P (OR:2.3, p<0.001) and P216L (OR:4.5, p<0.05) heterozygotes. In addition, carriers of E167K are at a 3-folded increase of at-risk MASH (OR:2.75, p<0.001). CT-derived liver fat scores were higher in E167K and L156P in an allele-dose manner (p<0.05). This corresponded with the UKB nuclear magnetic resonance-derived lipidomic analyses (N=105,348), revealing all carriers to exhibit lower total cholesterol, triglycerides and total choline. In silico predictions suggested that these missense variants cause structural disruptions in the EXPERA domain, leading to reduced protein function. This hypothesis was strengthened with a gene-burden of rare loss-of-function variants in TM6SF2 demonstrating an increased risk of SLD (OR:4.9, p<0.05), primarily driven by a novel rare stop-gain variant (W35X) in the same directionality. ConclusionThe functional genetic study of protein-altering variants provides insights on the association between loss of TM6SF2 function and steatotic liver disease and poses the bases for future mechanistic studies. Impact and implicationsThe genome-first approach expands insights into genetic risk factors for steatotic liver disease with TM6SF2 being a focal point due to its known association with plasma lipid traits. Our findings validated two missense variants (E167K and L156P) to be associated with increased risk of hepatic steatosis on CT and MRI scans, as well as the risk of clinically diagnosed hepatocellular carcinoma independent of the common PNPLA3 I48M risk variant. Notably, we also identified a predicted deleterious missense variant P216L to drive steatotic risk and demonstrated that an aggregated gene burden of rare variants demonstrating complete loss-of-function to be linked to the risk of hepatic steatosis. Combined, this study sets the stage for future mechanistic investigations into the functional consequences of TM6SF2 variants in metabolic dysfunction-associated steatotic liver disease to determine future therapeutic targets.

Dimeric natural product panepocyclinol A inhibits STAT3 via di-covalent modification

Homo- or heterodimeric compounds that affect dimeric protein function through interaction between monomeric moieties and protein subunits can serve as valuable sources of potent and selective drug candidates. Here, we screened an in-house dimeric natural product collection, and panepocyclinol A (PecA) emerged as a selective and potent STAT3 inhibitor with profound anti-tumor efficacy. Through cross-linking C712/C718 residues in separate STAT3 monomers with two distinct Michael receptors, PecA inhibits STAT3 DNA binding affinity and transcription activity. Molecular dynamics simulation reveals the key conformation changes of STAT3 dimers upon the di-covalent binding with PecA that abolishes its DNA interactions. Furthermore, PecA exhibits high efficacy against anaplastic large T cell lymphoma in vitro and in vivo, especially those with constitutively activated STAT3 or STAT3Y640F. In summary, our study describes a distinct and effective di-covalent modification for the dimeric compound PecA to disrupt STAT3 function.

An explore method for quick screening biomarkers based on effective enrichment capacity and data mining

Protein glycosylation acts as a crucial role in regulating protein function and maintaining cellular homeostasis. Efficient peptide enrichment can be utilized to effectively solve the inherent challenges of protein glycosylation analysis to search unknown cancer biomarkers. In this research, a low dimensional porous hydrophilic nanosheets with a multi-level porous structure (Co-MOF-SiO2@HA) was synthetized via an easy one-pot method for the efficient enrichment of the N-glycopeptides in the digests of complex biosamples. The synthetized nanosheets Co-MOF-SiO2@HA demonstrated excellent enriching performances including a high enrichment capacity (300 mg g-1 calculated), a spectacular selectivity (IgG digests and BSA digests at the molar ratio of 1/1200), and an excellent spatial confinement ability (IgG digests, IgG and BSA at the molar ratio of 1/1000/1000). As an explore result, after the enrichment of human colorectal cancer tissue and human healthy tissue by the nanosheets, several proteins related to cancers and one protein directly related to well-known human colorectal cancer were identified by detecting the corresponding glycopeptides. It presented the potential value of the feasibility of this analysis mode by nanosheets Co-MOF-SiO2@HA in proteomic analysis.

Discovery of PRMT3 Degrader for the Treatment of Acute Leukemia.

Protein arginine methyltransferase 3 (PRMT3) plays an important role in gene regulation and a variety of cellular functions, thus, being a long sought-after therapeutic target for human cancers. Although a few PRMT3 inhibitors are developed to prevent the catalytic activity of PRMT3, there is little success in removing the cellular levels of PRMT3-deposited ω-NG,NG-asymmetric dimethylarginine (ADMA) with small molecules. Moreover, the non-enzymatic functions of PRMT3 remain required to be clarified. Here, the development of a first-in-class MDM2-based PRMT3-targeted Proteolysis Targeting Chimeras (PROTACs) 11 that selectively reduced both PRMT3 protein and ADMA is reported. Importantly, 11 inhibited acute leukemia cell growth and is more effective than PRMT3 inhibitor SGC707. Mechanism study shows that 11 induced global gene expression changes, including the activation of intrinsic apoptosis and endoplasmic reticulum stress signaling pathways, and the downregulation of E2F, MYC, oxidative phosphorylation pathways. Significantly, the combination of 11 and glycolysis inhibitor 2-DG has a notable synergistic antiproliferative effect by further reducing ATP production and inducing intrinsic apoptosis, thus further highlighting the potential therapeutic value of targeted PRMT3 degradation. These data clearly demonstrated that degrader 11 is a powerful chemical tool for investigating PRMT3 protein functions.

Rapid Interpretation of Protein Backbone Rotation Dynamics Directly from Spin Relaxation Data.

Besides their structure, dynamics is pivotal for protein functions, particularly for intrinsically disordered proteins (IDPs) that do not fold into a fixed 3D structure. However, the detection of protein dynamics is difficult for IDPs and other disordered biomolecules. NMR spin relaxation rates are sensitive to the rapid rotations of chemical bonds, but their interpretation is arduous for IDPs or molecular assemblies with a complex dynamic landscape. Here we demonstrate numerically that the dynamics of a wide range of proteins, from short peptides to partially disordered proteins and peptides in micelles, can be characterized by calculating the total effective correlation times of protein backbone N-H bond rotations, τeff, from experimentally measured transverse 15N spin relaxation rates, R2, using a linear relation. Our results enable the determination of magnetic-field-independent and intuitively understandable parameters describing protein dynamics at different regions of the sequence directly from experiments. A practical advance of the approach is demonstrated by analyzing partially disordered proteins in which rotations of disordered regions occur with timescales of 1-2 ns, independent of their size, suggesting that rotations of disordered and folded regions are uncoupled in these proteins.

StarFunc: Accurate Protein Function Prediction Reveals Novel Human Proteins Involved in Ubiquitination

StarFunc: Accurate Protein Function Prediction Reveals Novel Human Proteins Involved in Ubiquitination

Activity-Based Acylome Profiling with N-(Cyanomethyl)-N-(phenylsulfonyl)amides for Targeted Lysine Acylation and Post-Translational Control of Protein Function in Cells.

Lysine acylations are ubiquitous and structurally diverse post-translational modifications that vastly expand the functional heterogeneity of the human proteome. Hence, the targeted acylation of lysine residues has emerged as a strategic approach to exert biomimetic control over the protein function. However, existing strategies for targeted lysine acylation in cells often rely on genetic intervention, recruitment of endogenous acylation machinery, or nonspecific acylating agents and lack methods to quantify the magnitude of specific acylations on a global level. In this study, we develop activity-based acylome profiling (ABAP), a chemoproteomic strategy that exploits elaborate N-(cyanomethyl)-N-(phenylsulfonyl)amides and lysine-centric probes for site-specific introduction and proteome-wide mapping of posttranslational lysine acylations in human cells. Harnessing this framework, we quantify various artificial acylations and rediscover numerous endogenous lysine acylations. We validate site-specific acetylation of target lysines and establish a structure-activity relationship for N-(cyanomethyl)-N-(phenylsulfonyl)amides in proteins from diverse structural and functional classes. We identify paralog-selective chemical probes that acetylate conserved lysines within interferon-stimulated antiviral RNA-binding proteins, generating de novo proteoforms with obstructed RNA interactions. We further demonstrate that targeted acetylation of a key enzyme in retinoid metabolism engenders a proteoform with a conformational change in the protein structure, leading to a gain-of-function phenotype and reduced drug potency. These findings underscore the versatility of our strategy in biomimetic control over protein function through targeted delivery and global profiling of endogenous and artificial lysine acylations, potentially advancing therapeutic modalities and our understanding of biological processes orchestrated by these post-translational modifications.

Deubiquitinases in skeletal muscle - The Underappreciated Side of the Ubiquitination Coin.

Ubiquitination is a post-translational modification that plays important roles in regulating protein stability, function, localization, and protein-protein interactions. Proteins are ubiquitinated via a process involving specific E1 activating enzymes, E2 conjugating enzymes, and E3 ligases. Simultaneously, protein ubiquitination is opposed by deubiquitinating enzymes (DUBs). DUB-mediated deubiquitination can change protein function or fate and recycle ubiquitin to maintain the free ubiquitin pool. Approximately 100 DUBs have been identified in the mammalian genome, and characterized into seven classes (USP, OTU, UCH, MJD, JAMM, MINDY and ZUP classes). Of these 100 DUBs, there has only been relatively limited investigation of 19 specifically in skeletal muscle cells, in vitro or in vivo, using overexpression, knockdown, and knockout models. To date, evidence indicates roles for individual DUBs in regulating aspects of myogenesis, protein turnover, muscle mass, and muscle metabolism. However, the exact mechanism by which these DUBs act (i.e. the specific targets of these DUBs and the type of ubiquitin chains they target) is still largely unknown, underscoring how little we know about DUBs in skeletal muscle. This review endeavors to comprehensively summarize the current state of knowledge of the function of DUBs in skeletal muscle and highlight the opportunities for gaining a greater understanding through further research into this important area of skeletal muscle and ubiquitin biology.

Methamphetamine-induced impairment of memory and fleeting neuroinflammation: Profiling mRNA changes in mouse hippocampus following short-term and long-term exposure

Methamphetamine (METH) has been implicated in inducing memory impairment, but the precise mechanisms underlying this effect remain unclear. Current research often limits itself to singular models or focuses on individual gene or protein functions, which hampers a comprehensive understanding of the underlying mechanisms. In this study, we established three METH mouse exposure models, extracted hippocampal nuclei, and utilized RNA sequencing to analyze changes in mRNA expression profiles. Our results indicate that METH significantly impairs the learning and memory capabilities of mice. Additionally, we observed that METH-induced inflammatory responses occur in the early phase and do not further exacerbate with repeated injections. However, RNA sequencing revealed the persistent enrichment of inflammatory pathway molecules, which correlated with worsened behaviors. This suggests that although METH-induced neuroinflammation plays a critical role in learning and memory impairment, the continued enrichment of inflammatory pathway molecules is associated with behavioral outcomes. These findings provide crucial evidence for the potential application of immune intervention in METH-related disorders.

Tailoring potential antigenic regions on pandemic SARS spike protein

Coronavirus-associated severe acute respiratory syndrome (SARS) pandemics have devastated lives, economies, and societies worldwide. Given the higher severity of the latter pandemic, the constant mutation, and vaccine escape, new and more dangerous pandemics could emerge. Therefore, it is imperative to identify conserved vaccine candidates for stable effectiveness in future pandemics. This study aimed to tailor potential, conserved peptide-based vaccine candidates for the upcoming Coronavirus pandemic based on the sequences of the spike protein of SARS-CoV-1 and SARS-CoV-2 viruses, using bioinformatic approaches. Peptide-based CD4+ T-cell epitopes derived from SARS proteomes were identified based on their predicted binding affinity to HLA-DRB1, one of the central molecules for the adaptive immune system. These epitopes were then assessed for conservation by sequence analysis of all pandemic-involved strains and variants. The epitopes were then evaluated and cross-checked for possible protection against the causative pathogens via potential uptake by B-cell receptors, the sustenance of sequence conservation for the future pandemic strain using data from population HLA-allele-typing studies, structural analysis of the spike-antibody complex and their contribution to the function of spike protein, respectively. As a result, selected vaccine candidates were projected to cover nearly 90% of the world's population with the combination of just four epitopes. The epitopes could be modified to adapt to future pandemic strains, improve antigenicity, or be used as booster immunization against the currently circulating SARS-CoV-2 variant. This study demonstrates that there is still room for improvement and promising discoveries in vaccine design to deter upcoming SARS pandemics.

Comparative Analysis of Intestinal TLR4 Gene Expression and Functional Verification in Lepus yarkandensis and Oryctolagus cuniculus.

Lepus yarkandensis live year-round in harsh desert environments and are less susceptible to enteritis. The living conditions of Oryctolagus cuniculus in captivity were suitable, but they were highly susceptible to death by Gram-negative bacteria infected with inflammatory bowel disease complex.TLR4 is closely related to the occurrence of enteritis, and the neighbor-joining topology based on the 12S rDNA sequences showed that the relationship between O. cuniculus and L. yarkandensis is as high as 98%.Therefore, we chose O. cuniculus and L. yarkandensis for comparative study.The purpose of this study was to investigate the role of Toll-like receptor 4 (TLR4) in the regulation of immunity and inflammation in the intestinal tract of L. yarkandensis. In this study, the TLR4 gene was cloned for the first time in the colon of L. yarkandensis. The expression of TLR4 in the intestinal tissues of L. yarkandensis and O. cuniculus was detected by histological observation, real-time fluorescence quantification PCR(qRT-PCR), and protein blotting (Western blot).An LPS-induced cell inflammation model was constructed in vitro, and ELISA was used to examine the effect of pEGFP-N1-TLR4 and siRNA knockout on the anti-inflammatory ability of the TLR4 gene. The results showed that the open reading frame of the L. yarkandensis TLR4 gene was 2520bp in length. Compared with the sequence of O. cuniculus, there were 15 differences in the TLR4 amino acid sequence of L. yarkandensis, 12 of which occurred in the LRR domain and 2 in the TIR domain, and the sequence changed from G to D at position 298. Immunohistochemistry showed that TLR4 was mainly expressed in the epithelial cells of the colon L. yarkandensis, and the expression level of TLR4 in the cecum and colon was significantly lower compared with that of O. cuniculus. qRT-PCR and Western blot results showed that the expression level of TLR4 in the colon of L. yarkandensis was significantly lower than that of O. cuniculus. At the cellular level, ELISA showed that overexpression of the TLR4 protein in L. yarkandensis could reduce the LPS-induced inflammatory response. Therefore, according to the above results, the protein structure and function of L. yarkandensis TLR4 may be different due to the change of nucleotide, which affects its binding with LPS and the activation of downstream molecules, so that L. yarkandensis is not prone to enteritis and can adapt to the harsh desert environment for a long time. This study also laid the foundation for improving the disease resistance of O. cuniculus and promoting the development and utilization of genes in L. yarkandensis.

The Role of Protein Post-Translational Modifications in Fruit Ripening

Fruit ripening represents a multifaceted biological process intricately controlled by an array of plant hormones, transcription factors, and epigenetic modifications. These regulatory mechanisms are crucial in determining fruit quality and post-harvest shelf life. Recent advancements in proteomics have shifted the focus toward understanding protein post-translational modifications (PTMs), which play a crucial role in modulating protein function. PTMs enhance protein activity and stability by altering their properties after biosynthesis, thereby adding an additional layer of regulation to the ripening process. This paper provides a comprehensive review of the roles of PTMs, including ubiquitination, phosphorylation, redox modifications, and glycosylation in regulating fruit ripening. Emphasis is placed on the intricate interplay between these PTMs and key regulator factors such as plant hormones, transcriptional mechanisms, and epigenetic modifications. By exploring these interactions, this review seeks to enhance our understanding of the complex regulatory network underlying fruit ripening and to offer novel perspectives on strategies for fruit preservation.

DNA-Based Molecular Clamp for Probing Protein Interactions and Structure under Force.

Cellular mechanotransduction, a process central to cell biology, embryogenesis, adult physiology, and multiple diseases, is thought to be mediated by force-driven changes in protein conformation that control protein function. However, methods to study proteins under defined mechanical loads on a biochemical scale are lacking. We report the development of a DNA-based device in which the transition between single- and double-stranded DNA applies tension to an attached protein. Using a fragment of the talin rod domain as a test case, negative-stain electron microscopy reveals programmable extension, while pull down assays show tension-induced binding to two ligands, ARPC5L and vinculin, known to bind to cryptic sites inside the talin structure. These results demonstrate the utility of the DNA clamp for biochemical studies and potential structural analysis.

V2 Protein Enhances the Replication of Genomic DNA of Mulberry Crinkle Leaf Virus.

Mulberry crinkle leaf virus (MCLV), identified in mulberry plants (Morus alba L.), is a member of the genus Mulcrilevirus in the family Geminiviridae. The functions of the V2 protein encoded by MCLV remain unclear. Here, Agrobacterium-mediated infectious clones of a wild-type MCLV vII (MCLVWT) and two V2 mutant MCLV vIIs, including MCLVmV2 (with a mutation of the start codon of the V2 ORF) and MCLVdV2 (5'-end partial deletion of the V2 ORF sequence), were constructed to investigate the roles of V2 both in planta and at the cellular level. Although all three constructs (pCA-1.1MCLVWT, pCA-MCLVmV2, and pCA-MCLVdV2) were able to infect both natural host mulberry plants and experimental tomato plants systematically, the replication of the MCLVmV2 and MCLVdV2 genomes in these hosts was significantly reduced compared to that of MCLVWT. Similarly, the accumulation of MCLVmV2 and MCLVdV2 in protoplasts of Nicotiana benthamiana plants was significantly lower than that of MCLVWT either 24 h or 48 h post-transfection. A complementation experiment further confirmed that the decreased accumulation of MCLV in the protoplasts was due to the absence of V2 expression. These results revealed that MCLV-encoded V2 greatly enhances the level of MCLV DNA accumulation and is designated the replication enhancer protein of MCLV.

A Proteogenomic Approach to Unveiling the Complex Biology of the Microbiome

The complex biology of the microbiome was elucidated once the genomics era began. The proteogenomic approach analyzes and integrates genetic makeup (genomics) and microbial communities′ expressed proteins (proteomics). Therefore, researchers gained insights into gene expression, protein functions, and metabolic pathways, understanding microbial dynamics and behavior, interactions with host cells, and responses to environmental stimuli. In this context, our work aims to bring together data regarding the application of genomics, proteomics, and bioinformatics in microbiome research and to provide new perspectives for applying microbiota modulation in clinical practice with maximum efficiency. This review also synthesizes data from the literature, shedding light on the potential biomarkers and therapeutic targets for various diseases influenced by the microbiome.

A Novel SPOTTED LEAF1-1 (SPL11-1) Gene Confers Resistance to Rice Blast and Bacterial Leaf Blight Diseases in Rice (Oryza sativa L.)

Programmed cell death (PCD) plays critical roles in plant immunity but must be regulated to prevent excessive damage. In this study, a novel spotted leaf (spl11-1) mutant was identified from an ethyl methane sulfonate (EMS) population. The SPL11-1 gene was genetically mapped to chromosome 12 between the Indel12-37 and Indel12-39 molecular markers, which harbor a genomic region of 27 kb. Annotation of the SPL11-1 genomic region revealed the presence of two candidate genes. Through gene prediction and cDNA sequencing, it was confirmed that the target gene in the spl11-1 mutant is allelic to the rice SPOTTED LEAF (SPL11), hereafter referred to as spl11-1. Sequence analysis of SPL11 revealed a single bp deletion (T) between the spl11-1 mutant and the ‘Shuangkang77009’ wild type. Moreover, protein structure analysis showed that the structural differences between the SPL11-1 and SPL11 proteins might lead to a change in the function of the SPL11 protein. Compared to the ‘Shuangkang77009’ wild type, the spl11-1 mutant showed more disease resistance. The agronomical evaluation showed that the spl11-1 mutant showed more adverse traits. Through further mutagenesis treatment, we obtained the spl11-2 mutant allelic to spl11-1, which has excellent agronomic traits and more improvement and may have certain breeding prospects in future breeding for disease resistance.

Crosstalk between BER and NHEJ in XRCC4-Deficient Cells Depending on hTERT Overexpression.

Targeting DNA repair pathways is an important strategy in anticancer therapy. However, the unrevealed interactions between different DNA repair systems may interfere with the desired therapeutic effect. Among DNA repair systems, BER and NHEJ protect genome integrity through the entire cell cycle. BER is involved in the repair of DNA base lesions and DNA single-strand breaks (SSBs), while NHEJ is responsible for the repair of DNA double-strand breaks (DSBs). Previously, we showed that BER deficiency leads to downregulation of NHEJ gene expression. Here, we studied BER's response to NHEJ deficiency induced by knockdown of NHEJ scaffold protein XRCC4 and compared the knockdown effects in normal (TIG-1) and hTERT-modified cells (NBE1). We investigated the expression of the XRCC1, LIG3, and APE1 genes of BER and LIG4; the Ku70/Ku80 genes of NHEJ at the mRNA and protein levels; as well as p53, Sp1 and PARP1. We found that, in both cell lines, XRCC4 knockdown leads to a decrease in the mRNA levels of both BER and NHEJ genes, though the effect on protein level is not uniform. XRCC4 knockdown caused an increase in p53 and Sp1 proteins, but caused G1/S delay only in normal cells. Despite the increased p53 protein, p21 did not significantly increase in NBE1 cells with overexpressed hTERT, and this correlated with the absence of G1/S delay in these cells. The data highlight the regulatory function of the XRCC4 scaffold protein and imply its connection to a transcriptional regulatory network or mRNA metabolism.