Non-homologous End Joining Research Articles

SelectRepair Knockout: Efficient PTC-Free Gene Knockout Through Selectable Homology-Directed DNA Repair.

Generating nonessential gene knockouts using CRISPR/Cas9 technology is becoming increasingly common in biological research. In a typical workflow, the Cas9 endonuclease is used to induce a DNA double-strand break that relies on nonhomologous end-joining (NHEJ) to introduce a premature termination codon (PTC) in the target gene. The goal is to isolate clones in which the gene produces PTC-containing mRNA transcripts that are degraded via nonsense-mediated mRNA decay (NMD) to cause loss of gene function. Unfortunately, this approach is laborious, and not all PTCs trigger NMD. More importantly, mounting evidence suggest that PTC mutations can also result in a transcriptional adaptation response that can mask the effects of a PTC-mediated gene knockout. In this chapter, we present a PTC-free gene knockout strategy that implements homology-directed DNA repair (HDR) with selectable markers to substantially reduce the complexity of the screening and validation of genome edits in cells containing more than one gene copy as in the case of the commonly used hypotriploid HEK293 cell line. We describe how to obtain a complete knockout of the Ligase IV protein (LIG4) and provide considerations for the application of this SelectRepair Knockout method to other genes.

Effect of PI3-kinase inhibitors on DNA double strand break repair pathways: observations using a site specific DSB induction system.

We established two types of site-specific DNA double strand breaks (DSB) induction systems to elucidate factors which affect the efficiency or quality of DSB repair. For mutation assays, a site specific DSB was generated by the transient expression of a zinc finger nuclease which targets the human HPRT1 gene. A cell line in which time and site specific DSBs can be generated in a HR reporter construct was used for homology-directed repair (HR) analysis. By using these two systems, we investigated the effects of PI3-kinase inhibitors on the efficiency and quality of DSB repair. Ataxia telangiectasia mutated (ATM) kinase inhibition resulted a decrease in mutant frequency and a slight increase in deletion-type mutations accompanied by microhomology. Furthermore, the HR frequency increased significantly when ATM kinase activity was inhibited. Thus, ATM kinase activity might be involved in the suppression of DSB end resection, and this may promote DSB repair through canonical non-homologous end joining.

Cas9/guide RNA-based gene-drive dynamics following introduction and introgression into diverse anopheline mosquito genetic backgrounds.

Novel technologies are needed to combat anopheline vectors of malaria parasites as the reductions in worldwide disease incidence has stalled in recent years. Gene drive-based approaches utilizing Cas9/guide RNA (gRNA) systems are being developed to suppress anopheline populations or modify them by increasing their refractoriness to the parasites. These systems rely on the successful cleavage of a chromosomal DNA target site followed by homology-directed repair (HDR) in germline cells to bias inheritance of the drive system. An optimal drive system should be highly efficient for HDR-mediated gene conversion with minimal error rates. A gene-drive system, AgNosCd-1, with these attributes has been developed in the Anopheles gambiae G3 strain and serves as a framework for further development of population modification strains. To validate AgNosCd-1 as a versatile platform, it must perform well in a variety of genetic backgrounds. We introduced or introgressed AgNosCd-1 into different genetic backgrounds, three in geographically-diverse Anopheles gambiae strains, and one each in an An. coluzzii and An. arabiensis strain. The overall drive inheritance, determined by presence of a dominant marker gene in the F2 hybrids, far exceeded Mendelian inheritance ratios in all genetic backgrounds that produced viable progeny. Haldane's rule was confirmed for AgNosCd-1 introgression into the An. arabiensis Dongola strain and sterility of the F1 hybrid males prevented production of F2 hybrid offspring. Back-crosses of F1 hybrid females were not performed to keep the experimental design consistent across all the genetic backgrounds and to avoid maternally-generated mutant alleles that might confound the drive dynamics. DNA sequencing of the target site in F1 and F2 mosquitoes with exceptional phenotypes revealed drive system-generated mutations resulting from non-homologous end joining events (NHEJ), which formed at rates similar to AgNosCd-1 in the G3 genetic background and were generated via the same maternal-effect mechanism. These findings support the conclusion that the AgNosCd-1 drive system is robust and has high drive inheritance and gene conversion efficiency accompanied by low NHEJ mutation rates in diverse An. gambiae s.l. laboratory strains.

CNSC-40. GTP SIGNALING PATHWAY PROMOTES NHEJ REPAIR BY INDUCING NUCLEAR ACTIN POLYMERIZATION IN GLIOBLASTOMA

Abstract OBJECTIVES We recently identified that GTP promotes non-homologous end joining (NHEJ) by triggering a GTP-Rac1-PP5-Abi-1/S323 cascade and we sought to define the molecular mechanisms. METHODS Crispr/Cas9, CDNA overexpression and immunoblot were used to modulate and confirm protein levels. Cellular fractionation and immunofluorescence (IF) were used to determine the localization of proteins. Laser micro-irradiation was used to induce DNA damage and monitor the recruitment of DNA repair proteins. RESULTS We found that GTP-activated protein Rac1 and Abi-1, the two key components of the newly identified pathway, shuttled into the nucleus post-RT in glioblastoma (GBM) cells. These effects were further enhanced by the GTP precursor guanosine but blocked by GTP depletion. Furthermore, Abi-1 and Rac1 accumulated in the nucleus of the cells expressing constitutively active Rac1 but not dominant negative Rac1 after RT, which suggests that Rac1/Abi-1 nuclear translocation is Rac1 activity dependent. We previously discovered that GTP-Rac1 promotes DNA repair by facilitating the dephosphorylation of Abi-1 (S323). Here, we discovered that dephosphomimetic Abi-1 (S323A) but not phosphomimetic Abi-1 (S323D) shuttled into nucleus after RT. Because Rac1 canonically binds to Abi-1 and promotes actin polymerization in the cytosol, we next wanted to determine if RT-induced nuclear Rac1/Abi-1/S323A could enhance nuclear actin polymerization, which could enhance NHEJ repair. We found that Abi-1/S323A but not Abi-1/S323D increases nuclear filament actin formation post-RT and activating the GTP-Rac1-Abi-1/S323A axis (through guanosine supplementation, expression of constitutively active Rac1 or expression of dephosphomimetic Abi-1/S323A) enhanced the recruitment and stability of KU80 at sites of DNA damage, which could be blocked by actin polymerization inhibitor cytochalasin D. Furthermore, inhibiting actin polymerization overcame radiation resistance in GBM cells with an active GTP-Rac1-Abi-1/S323A axis. CONCLUSIONS GTP-Rac1-PP5-Abi-1/S323 cascade promotes NHEJ repair by inducing the nuclear assembly of filament actin and disrupting this regulation could improve treatment responses in GBMs.

DNAR-16. TARGETING APOBEC CYTIDINE DEAMINASES TO ENHANCE RADIOSENSITIVITY IN GLIOMA

Abstract Glioma is the most common and aggressive primary adult brain tumor. Radiation therapy (RT) is a critical part of glioma treatment, but radioresistance severely limits its therapeutic efficacy. To better understand how radioresistance develops, we analyzed 212 paired primary and recurrent gliomas from the Glioma Longitudinal Analysis Consortium. We found a significant increase in mutational signatures associated with the activity of the Apolipoprotein B mRNA-editing enzyme catalytic polypeptide-like (APOBEC) family of cytidine deaminases in RT-treated recurrent gliomas (p<0.001, paired Wilcoxon signed-rank test). Further analysis of post-treatment mutations showed that RT increased APOBEC mutational signatures independent of other factors (p<0.001, multivariable log-linear regression), suggesting that APOBEC proteins become activated by radiation. However, their role in promoting tumor evolution and treatment resistance is currently unknown. Further analyses of extended signature contexts and expression data nominated APOBEC3B (A3B) and APOBEC3G (A3G) as candidates for creating these mutational signatures. To investigate their roles in RT response, we knocked out (KO) A3B and A3G individually in patient-derived glioma cell lines before RT. Compared to Control cells, irradiated A3B-KO and A3G-KO cells acquired significantly fewer APOBEC mutational signatures by whole genome sequencing (p<0.05, Kruskal–Wallis test) and exhibited enhanced radiosensitivity in vitro. Interestingly, the KO cells displayed a significant decrease in mutational signatures associated with Non-Homologous End-Joining (NHEJ), one of the main pathways for repairing the RT-induced DNA damage (p<0.05, Kruskal–Wallis test), suggesting that APOBEC deletion impaired DNA repair. This was further supported by persistent gH2AX DNA damage foci 48h post-RT and reduced autophosphorylation of DNA-dependent protein kinase (DNA-PK), a vital component of the NHEJ pathway, particularly in A3G KO cells. Overall, our results identify APOBEC proteins as potential targets for radiosensitizing gliomas and highlight the clinical utility of using mutational signatures to predict and monitor response to treatment.

HPV and p53 status as precision determinants of head and neck cancer response to DNA-PKcs inhibition in combination with irradiation.

Major risk factors of head and neck squamous cell carcinoma (HNSCC) are tobacco use and human papillomavirus (HPV). HPV E6 oncoprotein leads to p53 degradation, whereas HPV-negative cancers are frequently associated with TP53 mutations. Peposertib is a potent and selective, orally administered small-molecule inhibitor of the catalytic subunit of the DNA-dependent kinase (DNA-PKcs), a key regulator of non-homologous end joining (NHEJ). NHEJ inhibition along with irradiation (IR)-induced DNA double-strand breaks has the potential to increase antitumor treatment efficacy. Here, we investigated the responses of a panel of HNSCC models with distinct HPV and p53 status to treatments with IR, DNA-PKcs inhibition, and their combination in-vitro and in-vivo. IR-induced DNA damage combined with peposertib administration shortly before IR results in decreased cell viability and proliferation and causes DNA repair delay in all studied HNSCC cell lines. However, our data confirm that the actual cell fate upon this treatment is determined by cellular p53 and/or HPV status. Cells lacking functional p53 due to its degradation by HPV or due to a loss-of-function mutation are arrested in the G2/M phase of the cell cycle and eliminated by apoptosis whereas p53-proficient HNSCC cell lines preferentially undergo senescence. This is also recapitulated in-vivo, where HPV+ UD-SCC-2 xenografts display stronger and more durable responses to the combined treatment as compared to p53 wild-type UM-SCC-74A tumors. In conclusion, DNA-PKcs inhibitor peposertib should be further studied as a potential radiosensitizer for HNSCCs, taking into consideration the genetic background and the HPV status of a particular tumor.

TPX2 serves as a novel target for expanding the utility of PARPi in pancreatic cancer through conferring synthetic lethality

BackgroundPARP inhibitors (PARPi) have been licensed for the maintenance therapy of patients with metastatic pancreatic cancer carrying pathogenic germline BRCA1/2 mutations. However, mutations in BRCA1/2 are notably rare in pancreatic...

The Role of Microhomology-Mediated End Joining (MMEJ) at Dysfunctional Telomeres.

DNA double-strand break (DSB) repair pathways are crucial for maintaining genome stability and cell viability. However, these pathways can mistakenly recognize chromosome ends as DNA breaks, leading to adverse outcomes such as telomere fusions and malignant transformation. The shelterin complex protects telomeres from activation of DNA repair pathways by inhibiting nonhomologous end joining (NHEJ), homologous recombination (HR), and microhomology-mediated end joining (MMEJ). The focus of this paper is on MMEJ, an error-prone DSB repair pathway characterized by short insertions and deletions flanked by sequence homology. MMEJ is critical in mediating telomere fusions in cells lacking the shelterin complex and at critically short telomeres. Furthermore, studies suggest that MMEJ is the preferred pathway for repairing intratelomeric DSBs and facilitates escape from telomere crisis. Targeting MMEJ to prevent telomere fusions in hematologic malignancies is of potential therapeutic value.

Nuclear porcupine mediates XRCC6/Ku70 S-palmitoylation in the DNA damage response

BackgroundThe activation of the DNA damage response (DDR) heavily relies on post-translational modifications (PTMs) of proteins, which play a crucial role in the prevention of genetic instability and tumorigenesis. Among these PTMs, palmitoylation is a highly conserved process that is dysregulated in numerous cancer types. However, its direct involvement in the DDR and the underlying mechanisms remain unclear.MethodsCRISPR-Cas9 technology was used to generate the PORCN KO and PORCN NLS KO cell lines. The effects of PORCN NLS in the DDR were verified by colony formation assays, MTT assays, the DR/EJ5 homologous recombination/non-homologous end-joining reporter system, xenograft tumor growth and immunofluorescence. Mechanisms were explored by mass spectrometry, acyl-biotin exchange (ABE) palmitoylation assay, Click-iT assay, cell subcellular fractionation assay, Western blot analysis, and in vivo and in vitro co-immunoprecipitation.ResultsIn this study, we introduce evidence that Porcupine (PORCN) is an integral component of and plays a critical role in the DDR. PORCN deficiency hampers nonhomologous end joining (NHEJ) and highly sensitizes cells to ionizing radiation (IR) both in vitro and in vivo. We also provide evidence that PORCN possesses a nuclear fraction (nPORCN) with S-acyltransferase activity, unlike its membrane-bound O-acyltransferase in the endoplasmic reticulum. Furthermore, we show that nPORCN is necessary for the successful activation of NHEJ. Using mass spectrometry, we reveal the existence of an nPORCN complex and show that nPORCN mediates the S-palmitoylation of XRCC6/Ku70 at five specific cysteine sites in response to IR. Mutation of these sites causes a substantial increase in radiosensitivity and delays NHEJ. Additionally, we present evidence that nPORCN-dependent Ku70 palmitoylation is required for DNA-PKcs/Ku70/Ku80 complex formation.ConclusionOur findings underscore the crucial role of nPORCN-dependent Ku70 S-palmitoylation in the DDR.

One-ended and two-ended breaks at nickase-broken replication forks

Replisome collision with a nicked parental DNA template can lead to the formation of a replication-associated double strand break (DSB). How this break is repaired has implications for cancer initiation, cancer therapy and therapeutic gene editing. Recent work shows that collision of a replisome with a nicked DNA template can give rise to either a single-ended (se) or a double-ended (de)DSB, with potentially divergent effects on repair pathway choice and genomic instability. Emerging evidence suggests that the biochemical environment of the broken mammalian replication fork may be specialized in such a way as to skew repair in favor of homologous recombination at the expense of non-homologous end joining.

Disruption of RNA Splicing Increases Vulnerability of Cells to DNA-PK Inhibitors.

DNA-dependent protein kinase (DNA-PK) is a key effector of non-homologous end joining (NHEJ)-mediated double-strand break (DSB) repair. Since its identification, a substantial body of evidence has demonstrated that DNA-PK is frequently overexpressed in cancer, plays a critical role in tumor development and progression, and is associated with poor prognosis in cancer patients. Recent studies have also uncovered novel functions of DNA-PK, shifting the paradigm of the role of DNA-PK in oncogenesis and renewing interest in targeting DNA-PK for cancer therapy. To gain genetic insight into the cellular pathways requiring DNA-PK activity, we used a CRISPR/Cas9 screen to identify genes in which defects cause hypersensitivity to DNA-PK inhibitors. We identified over one hundred genes involved in DNA replication, cell cycle regulation, and RNA processing that promoted cell survival when DNA-PK kinase activity was suppressed. This gene set will be useful for characterizing novel biological processes that require DNA-PK activity and identifying predictive biomarkers of response to DNA-PK inhibition in the clinic. We also validated several genes from this set and reported previously undescribed genes that modulate the response to DNA-PK inhibitors. In particular, we found that compromising the mRNA splicing pathway led to marked hypersensitivity to DNA-PK inhibition, providing a possible rationale for the combined use of splicing inhibitors and DNA-PK inhibitors for cancer therapy.

CRISPR System and Its Applications in Medicine and Stem Cell Engineering

Context: The clustered regularly interspaced short palindromic repeat (CRISPR)/Cas system is a groundbreaking gene-editing tool that shows great promise for modifying genomes. Derived from prokaryotic adaptive immune defense mechanisms, this technique has been used in research on human diseases, demonstrating remarkable therapeutic potential. Through CRISPR, specific genetic mutations in patients can be corrected during gene therapy, offering a solution for treating diseases that were previously untreatable using conventional methods. This review explores the recent progress and future prospects of the CRISPR system, focusing on its applications in medicine and stem cell engineering. Special emphasis is placed on medical applications, the latest target design or analysis tools for genome editing, advancements in stem cell engineering, and associated innovations and challenges. Evidence Acquisition: This study reviewed articles indexed in ISI, SID, PubMed, and PubMed Central from 2007 to 2024. Results: Cas9, a key protein in CRISPR gene editing, is an endonuclease capable of targeting and cutting specific DNA sequences, guided by short RNA sequences. The gene editing process involves homology-directed repair (HDR), non-homologous end joining (NHEJ), and base editing pathways. Base editing, which modifies the epigenome without inducing DNA breaks, is gaining increasing attention. However, CRISPR still faces technical challenges, and the development of more efficient "super" CRISPR technology will likely require time. This article reviews the effectiveness, limitations, and applications of the CRISPR system. Conclusions: CRISPR/Cas9 tools allow for the creation of precise models, leading to more effective treatment options for patients.

Tissue microarray analyses of the essential DNA repair factors ATM, DNA-PKcs and Ku80 in head and neck squamous cell carcinoma

BackgroundHead and neck squamous cell carcinoma (HNSCC) negative for Human Papillomavirus (HPV) has remained a difficult to treat entity, whereas tumors positive for HPV are characterized by radiosensitivity and favorable patient outcome. On the cellular level, radiosensitivity is largely governed by the tumor cells` ability to repair radiation-induced DNA double-strand breaks (DSBs), but no biomarker is established that could guide clinical decision making. Therefore, we tested the impact of the expression levels of ATM, the central kinase of the DNA damage response as well as DNA-PKcs and Ku80, two major factors in the main DSB repair pathway non-homologous end joining (NHEJ).MethodsA tissue microarray of a single center HNSCC cohort was stained for ATM, DNA-PKcs and Ku80 and the expression scored based on staining intensity and the percentages of tumor cells stained. Scores were correlated with clinicopathological parameters and survival.ResultsSamples from 427 HNSCC patients yielded interpretable stainings and were scored following an established algorithm. The majority of tumors showed strong expression of both NHEJ factors, whereas the expression of ATM varied more. The expression scores of ATM and DNA-PKcs were not associated with patient survival. For HPV-negative HNSCC, the minority of tumors without strong Ku80 expression trended towards superior survival when treatment included radiotherapy. Focusing stronger on staining intensity to define the subgroup with lowest and therefore potentially insufficient expression levels in the HPV-negative subgroup, we observed significantly better overall survival for patients treated with radiotherapy but not with surgery alone.ConclusionsOur data suggest that HPV-negative HNSCC with particularly low Ku80 expression represent a highly radiosensitive subpopulation. Confirmation in independent cohorts is required.

Enhancing cisplatin efficacy in hepatocellular carcinoma with selenocystine: The suppression of DNA repair and inhibition of proliferation in hepatoma cells

Cisplatin (cDDP) is a crucial chemotherapy drug for treating various cancers, including hepatocellular carcinoma (HCC). However, its effectiveness is often hindered by side effects and drug resistance. Selenocystine (SeC) demonstrates potential as an anticancer agent, particularly by inhibiting DNA repair mechanisms. This study explored the synergistic potential of SeC combined with cDDP for treating HCC. Our results show that SeC pretreatment followed by cDDP significantly suppresses HCC cell proliferation more effectively than either treatment alone, with minimal toxicity to normal liver cells. The combination induces significant DNA damage by inhibiting homologous recombination (HR) and non-homologous end joining (NHEJ) pathways. Xenograft experiments confirmed that the combined therapy strongly inhibits tumor growth. SeC boost the effectiveness of cDDP by amplifying DNA damage and inhibiting DNA repair, presenting a promising approach to enhancing liver cancer treatment.

The decrease in Rad51 and DNA ligase IV nuclear protein expression in Msh2 knockdown HC11 cells induced the low CRISPR/Cas9-mediated knock-in efficiency at the β-casein gene locus.

Successful gene editing technology is crucial in molecular biology and related fields. An essential part of an efficient knock-in system is increasing homologous recombination (HR) efficiency in the double-strand break (DSB) repair pathways. Interestingly, HR is closely related to the DNA mismatch repair (MMR) pathway, whereby MMR-related gene Msh2 recognizes a mismatch of nucleotides in recombinant intermediates or gene conversion formed during HR. This study aimed to investigate how the knockdown of Msh2 affects HR-mediated knock-in efficiency at the mouse β-casein locus. Therefore, we investigated the effect of inhibiting Msh2 expression on the expression of the HR-related gene Rad51 and the key enzyme DNA ligase IV involved in non-homologous end joining (NHEJ). The knock-in vector targeting the mouse β-casein gene locus, programmed guide RNA, and Msh2 siRNA expression vector were co-transfected in HC11 cells, or only the Msh2 siRNA expression vector was transfected. Knock-in efficiency was confirmed by polymerase chain reaction (PCR). The mRNA and protein expression of Msh2, HR-related gene Rad51, and NHEJ-related gene DNA ligase IV were evaluated by quantitative reverse transcription PCR (RT-qPCR) and Western blot analysis. The knock-in vector efficiency at the mouse β-casein gene locus significantly decreased upon Msh2 knockdown in HC11 mouse mammary epithelial cells (HC11 cell). Additionally, the knockdown of the DNA MMR-related gene Msh2 protein significantly downregulated the nuclear protein expression of the HR-related Rad51 and NHEJ-related DNA ligase IV genes. The decreased Msh2 protein expression in the nucleus downregulated the Rad51 and ligase IV protein expressions. Consequently, reduced Rad51 expression results in decreased knock-in efficiency.

Non-classical action of Ku70 promotes Treg suppressive function through a FOXP3-dependent mechanism in lung adenocarcinoma.

Ku70, a DNA repair protein, binds to the damaged DNA ends and orchestrates the recruitment of other proteins to facilitate repair of DNA double-strand breaks. Besides its essential role in DNA repair, several studies have highlighted non-classical functions of Ku70 in cellular processes. However, its function in immune homeostasis and anti-tumor immunity remains unknown. Here, we discovered a marked association between elevated Ku70 expression and unfavorable prognosis in lung adenocarcinoma, focusing specifically on increased Ku70 levels in tumor-infiltrated Treg cells. Using a lung-colonizing tumor model of in mice with Treg-specific Ku70 deficiency, we demonstrated that deletion of Ku70 in Treg cells led to a stronger anti-tumor response and slower tumor growth due to impaired immune-suppressive capacity of Treg cells. Furthermore, we confirmed that Ku70 played a critical role in sustaining the suppressive function of human Treg cells. We found that Ku70 bound to FOXP3 and occupied FOXP3-bound genomic sites to support its transcriptional activities. These findings not only unveil a non-homologous end joining (NHEJ)-independent role of Ku70 crucial for Treg suppressive function, but also underscore the potential of targeting Ku70 as an effective strategy in cancer therapy, aiming to both restrain cancer cells and enhance pulmonary anti-tumor immunity.

Enhancing CRISPR-Cas-based gene targeting in tomato using a dominant-negative ku80

Abstract The CRISPR-Cas-based gene targeting (GT) method has enabled precise modifications of genomic DNA ranging from single base to several kilobase scales through homologous recombination (HR). In plant somatic cells, canonical nonhomologous end-joining (cNHEJ) is the predominant mechanism for repairing double-stranded breaks (DSBs), thus limiting the HR-mediated GT. In this study, we implemented an approach to shift the repair pathway preference toward HR by using a dominant-negative ku80 mutant protein (KUDN) to disrupt the initiation of cNHEJ. The employment of KUDN conferred a 1.71- to 3.55-fold improvement in GT efficiency at the callus stage. When we screened transformants, there was a more remarkable increase in GT efficiency, ranging from 1.62- to 9.84-fold, at two specific tomato loci, SlHKT1;2 and SlEPSPS1. With practical levels of efficiency, this enhanced KUDN-based GT tool successfully facilitated a 9-bp addition at an additional locus, SlCAB13. These findings provide another promising method for more efficient and precise plant breeding.

RAD51 recombinase and its paralogs: Orchestrating homologous recombination and unforeseen functions in protozoan parasites

The DNA of protozoan parasites is highly susceptible to damage, either induced by environmental agents or spontaneously generated during cellular metabolism through reactive oxygen species (ROS). Certain phases of the cell cycle, such as meiotic recombination, and external factors like ionizing radiation (IR), ultraviolet light (UV), or chemical genotoxic agents further increase this susceptibility. Among the various types of DNA damage, double-stranded breaks (DSBs) are the most critical, as they are challenging to repair and can result in genetic instability or cell death. DSBs caused by environmental stressors are primarily repaired via one of two major pathways: non-homologous end joining (NHEJ) or homologous recombination (HR). In multicellular eukaryotes, NHEJ predominates, but in unicellular eukaryotes such as protozoan parasites, HR seems to be the principal mechanism for DSB repair. The HR pathway is orchestrated by proteins from the RAD52 epistasis group, including RAD51, RAD52, RAD54, RAD55, and the MRN complex. This review focuses on elucidating the diverse roles and significance of RAD51 recombinase and its paralogs in protozoan parasites, such as Acanthamoeba castellanii, Entamoeba histolytica (Amoebozoa), apicomplexan parasites (Chromalveolata), Naegleria fowleri, Giardia spp., Trichomonas vaginalis, and trypanosomatids (Excavata), where they primarily function in HR. Additionally, we analyze the diversity of proteins involved in HR, both upstream and downstream of RAD51, and discuss the implications of these processes in parasitic protozoa.

Competition between homologous chromosomal DNA and exogenous donor DNA to repair CRISPR/Cas9-induced double-strand breaks in Aspergillus niger

BackgroundAspergillus niger is well-known for its high protein secretion capacity and therefore an important cell factory for homologous and heterologous protein production. The use of a strong promoter and multiple gene copies are commonly used strategies to increase the gene expression and protein production of the gene of interest (GOI). We recently presented a two-step CRISPR/Cas9-mediated approach in which glucoamylase (glaA) landing sites (GLSs) are introduced at predetermined sites in the genome (step 1), which are subsequently filled with copies of the GOI (step 2) to achieve high expression of the GOI.ResultsHere we show that in a ku70 defective A. niger strain (Δku70), thereby excluding non-homologous end joining (NHEJ) as a mechanism to repair double-stranded DNA breaks (DSBs), the chromosomal glaA locus or homologous GLSs can be used to repair Cas9-induced DSBs, thereby competing with the integration of the donor DNA containing the GOI. In the absence of exogenously added donor DNA, the DSBs are repaired with homologous chromosomal DNA located on other chromosomes (inter-chromosomal repair) or, with higher efficiency, by a homologous DNA fragment located on the same chromosome (intra-chromosomal repair). Single copy inter-chromosomal homology-based DNA repair was found to occur in 13–20% of the transformants while 80–87% of the transformants were repaired by exogenously added donor DNA. The efficiency of chromosomal repair was dependent on the copy number of the potential donor DNA sequences in the genome. The presence of five homologous DNA sequences, resulted in an increased number (35–61%) of the transformants repaired by chromosomal DNA. The efficiency of intra-chromosomal homology based DSB repair in the absence of donor DNA was found to be highly preferred (85–90%) over inter-chromosomal repair. Intra-chromosomal repair was also found to be the preferred way of DNA repair in the presence of donor DNA and was found to be locus-dependent.ConclusionThe awareness that homologous chromosomal DNA repair can compete with donor DNA to repair DSB and thereby affecting the efficiency of multicopy strain construction using CRISPR/Cas9-mediated genome editing is an important consideration to take into account in industrial strain design.

The epistatic relationship of Drosophila melanogaster CtIP and Rif1 in homology-directed repair of DNA double-strand breaks.

Double-strand breaks (DSBs) are genotoxic DNA lesions that pose significant threats to genomic stability, necessitating precise and efficient repair mechanisms to prevent cell death or mutations. DSBs are repaired through nonhomologous end-joining (NHEJ) or homology-directed repair (HDR), which includes homologous recombination (HR) and single-strand annealing (SSA). CtIP and Rif1 are conserved proteins implicated in DSB repair pathway choice, possibly through redundant roles in promoting DNA end-resection required for HDR. Although the roles of these proteins have been well-established in other organisms, the role of Rif1 and its potential redundancies with CtIP in Drosophila melanogaster remain elusive. To examine the roles of DmCtIP and DmRif1 in DSB repair, this study employed the direct repeat of white (DR-white) assay, tracking across indels by decomposition (TIDE) analysis, and P{wIw_2 kb 3'} assay to track repair outcomes in HR, NHEJ, and SSA, respectively. These experiments were performed in DmCtIPΔ/Δ single mutants, DmRif1Δ/Δ single mutants, and DmRif1Δ/Δ; DmCtIPΔ/Δ double mutants. This work demonstrates significant defects in both HR and SSA repair in DmCtIPΔ/Δ and DmRif1Δ/Δ single mutants. However, experiments in DmRif1Δ/Δ; DmCtIPΔ/Δ double mutants reveal that DmCtIP is epistatic to DmRif1 in promoting HDR. Overall, this study concludes that DmRif1 and DmCtIP do not perform their activities in a redundant pathway, but rather DmCtIP is the main driver in promoting HR and SSA, most likely through its role in end resection.