Molecular Detection of Nosema spp. in Honey in Bulgaria

Environmental DNA (eDNA) analysis is related to screening genetic material of various organisms in environmental samples. Honey represents a natural source of exogenous DNA, which allows for the detection of different honey bee pathogens and parasites. In the present study, we extracted DNA from 20 honey samples from different regions in Bulgaria and tested for the presence of DNA of the ectoparasitic mite Varroa destructor, as well as Nosema apis and Nosema ceranae. Only Nosema ceranae was detected, showing up in 30% of all samples, which confirms the widespread prevalence of this pathogen. All positive samples were found in plain regions of the country, while this pathogen was not detected in mountainous parts. None of the samples gave positive amplifications for the Nosema apis and Varroa mite. The obtained results from this study confirm previous observations that eDNA contained in honey is a potent source for effective biomonitoring of actual diseases in the honey bee.

Improvement of mRNA Delivery Efficiency to a T Cell Line by Modulating PEG-Lipid Content and Phospholipid Components of Lipid Nanoparticles

(1) Background: T cells are important target cells, since they exert direct cytotoxic effects on infected/malignant cells, and affect the regulatory functions of other immune cells in a target antigen-specific manner. One of the current approaches for modifying the function of T cells is gene transfection by viral vectors. However, the insertion of the exogenous DNA molecules into the genome is attended by the risk of mutagenesis, especially when a transposon-based gene cassette is used. Based on this scenario, the transient expression of proteins by an in vitro-transcribed messenger RNA (IVT-mRNA) has become a subject of interest. The use of lipid nanoparticles (LNPs) for the transfection of IVT-mRNA is one of the more promising strategies for introducing exogenous genes. In this study, we report on the development of LNPs with transfection efficiencies that are comparable to that for electroporation in a T cell line (Jurkat cells). (2) Methods: Transfection efficiency was improved by optimizing the phospholipids and polyethylene glycol (PEG)-conjugated lipid components. (3) Results: Modification of the lipid composition resulted in the 221-fold increase in luciferase activity compared to a previously optimized formulation. Such a high transfection activity was due to the efficient uptake by clathrin/dynamin-dependent endocytosis and the relatively efficient escape into the cytoplasm at an early stage of endocytosis.

Structure-driven effects on genomic DNA damage propensity at G-quadruplex sites

Our genome contains about half a million sites capable of forming G-quadruplex (G4) structures. Such structural formations, often localised at important regulatory loci, have high capability of altering the predisposition of corresponding genomic spans to endogenous and exogenous DNA damage. In this work, we devised an approach to systematically enrich and zoom onto structure-driven effects on the propensity to undergo 9 types of DNA damage: ultraviolet radiation-induced pyrimidine-pyrimidone (6-4) photoproduct PP and cyclobutane pyrimidine dimer CPD couplings (two dyad-based subtypes in each), cisplatin-mediated G-G crosslinks, reactive oxygen species induced 8-oxoguanine damage, DNA fragmentation upon natural decay and fossilisation, breakages from artificial enzymatic cleavage and ultrasound sonication. Our results indicate that the structural effects on DNA damageability at G4 sites are not a simple combination of shielding (G4 strand) and de-shielding (opposite strand) against damaging factors, and the outcomes have different patterns and variation from one damage type to another, highly dependent on the G4 strength and relative strand localisation. The results are accompanied by electronic structure calculations, detailed structural parallels and considerations.

Advances and Perspectives of Transgenic Technology and Biotechnological Application in Forest Trees

Transgenic technology is increasingly used in forest-tree breeding to overcome the disadvantages of traditional breeding methods, such as a long breeding cycle, complex cultivation environment, and complicated procedures. By introducing exogenous DNA, genes tightly related or contributed to ideal traits—including insect, disease, and herbicide resistance—were transferred into diverse forest trees, and genetically modified (GM) trees including poplars were cultivated. It is beneficial to develop new varieties of GM trees of high quality and promote the genetic improvement of forests. However, the low transformation efficiency has hampered the cultivation of GM trees and the identification of the molecular genetic mechanism in forest trees compared to annual herbaceous plants such as Oryza sativa. In this study, we reviewed advances in transgenic technology of forest trees, including the principles, advantages and disadvantages of diverse genetic transformation methods, and their application for trait improvement. The review provides insight into the establishment and improvement of genetic transformation systems for forest tree species. Challenges and perspectives pertaining to the genetic transformation of forest trees are also discussed.

Characterization of subcellular localization of eukaryotic clamp loader/unloader and its regulatory mechanism

Proliferating cell nuclear antigen (PCNA) plays a critical role as a processivity clamp for eukaryotic DNA polymerases and a binding platform for many DNA replication and repair proteins. The enzymatic activities of PCNA loading and unloading have been studied extensively in vitro. However, the subcellular locations of PCNA loaders, replication complex C (RFC) and CTF18-RFC-like-complex (RLC), and PCNA unloader ATAD5-RLC remain elusive, and the role of their subunits RFC2-5 is unknown. Here we used protein fractionation to determine the subcellular localization of RFC and RLCs and affinity purification to find molecular requirements for the newly defined location. All RFC/RLC proteins were detected in the nuclease-resistant pellet fraction. RFC1 and ATAD5 were not detected in the non-ionic detergent-soluble and nuclease-susceptible chromatin fractions, independent of cell cycle or exogenous DNA damage. We found that small RFC proteins contribute to maintaining protein levels of the RFC/RLCs. RFC1, ATAD5, and RFC4 co-immunoprecipitated with lamina-associated polypeptide 2 (LAP2) α which regulates intranuclear lamin A/C. LAP2α knockout consistently reduced detection of RFC/RLCs in the pellet fraction, while marginally affecting total protein levels. Our findings strongly suggest that PCNA-mediated DNA transaction occurs through regulatory machinery associated with nuclear structures, such as the nuclear matrix.

Abundant CpG-sequences in human genomes inhibit KIR3DL2-expressing NK cells

Killer Immunoglobulin-like Receptors (KIR) comprise a diverse, highly polymorphic family of cell-surface glycoproteins that are principally expressed by Natural Killer (NK) cells. These innate immune lymphocytes fulfill vital functions in human reproduction and immune responses to viral infection. KIR3DL2 is an inhibitory NK cell receptor that recognizes a common epitope of the HLA-A3 and HLA-A11 class I glycoproteins of the major histocompatibility complex. KIR3DL2 also binds exogenous DNA containing the CpG motif. This interaction causes internalization of the KIR-DNA. Exogenous CpG-DNA typically activates NK cells, but the specificity of KIR3DL2-DNA binding and internalization is unclear. We hypothesized that KIR3DL2 binds exogenous DNA in a sequence-specific manner that differentiates pathogen DNA from self-DNA. In testing this hypothesis, we surveyed octameric CpG-DNA sequences in the human genome, and in reference genomes of all bacteria, fungi, viruses, and parasites, with focus on medically relevant species. Among all pathogens, the nucleotides flanking CpG motifs in the genomes of parasitic worms that infect humans are most divergent from those in the human genome. We cultured KIR3DL2+NKL cells with the commonest CpG-DNA sequences in either human or pathogen genomes. DNA uptake was negatively correlated with the most common CpG-DNA sequences in the human genome. These CpG-DNA sequences induced inhibitory signaling in KIR3DL2+NKL cells. In contrast, KIR3DL2+NKL cells lysed more malignant targets and produced more IFNγ after culture with CpG-DNA sequences prevalent in parasitic worms. By applying functional immunology to evolutionary genomics, we conclude that KIR3DL2 allows NK cells to differentiate self-DNA from pathogen DNA.

The Loss of ALDH9A1 Is a Significant Source of Endogenous DNA Damage Which May be Reversed By the Inhibition of Polyamine Transport System

Fanconi anemia (FA) is the most common inherited bone marrow failure (BMF) syndrome and is caused by impaired DNA interstrand crosslink repair. FA patients usually develop BMF during the first decade of life, prior to any known exposure to exogenous crosslinking agents. Therefore, endogenous sources of DNA damage likely play an important role in the pathogenesis of FA. We previously identified loss of ALDH9A1 as a significant source of endogenous DNA damage using a metabolism-focused CRISPR knockout (KO) screen. This finding was validated using Jurkat cells as well as human hematopoietic stem and progenitor cells. Here, we present updates of our project. To determine whether endogenous DNA damage was induced by the combined loss of FANCD2 and ALDH9A1, we investigated markers of DNA damage in bulk-edited cells. We found that the numbers of chromosomal breaks, 53BP1 foci, and gamma-H2AX foci were increased in FANCD2-/-ALDH9A1-/- cells, compared with single KO or wildtype (WT) controls, in the absence of an exogenous DNA damaging agent. These findings are consistent with spontaneously increased basal levels of DNA damage in FANCD2-/-ALDH9A1-/- cells. To study in vivo BMF and tumorigenesis phenotypes of ALDH9A1 deficiency in the setting of FA, we generated a mouse model. Fanca-/-Aldh9a1-/- mice showed the lowest frequency of long-term hematopoietic stem cells and lineage-negative Sca-1-positive cKit-positive cells, however the differences were not significant compared with control groups. While we did not observe aplastic anemia or leukemia, we found a higher incidence of solid tumors, most notably ovarian tumors and hepatocellular carcinoma in aged Fanca-/-Aldh9a1-/- mice. This suggests that the level of endogenous reactive aldehydes created by ALDH9A1 deficiency in mouse is not high enough to cause full-blown hematopoietic phenotypes, most likely due to redundant detoxification pathways. However, in tissues where ALDH9A1 is active and non-redundant, the low level of endogenous DNA damage accumulating over time causes solid tumors. To identify the specific reactive aldehydes responsible for DNA damage in ALDH9A1 deficiency, we performed a growth selection screen using FANCD2-/-ALDH9A1-/- cells. We found that the loss of ATP13A3 conferred survival advantage to FANCD2-/-ALDH9A1-/- cells. ATP13A3 transports endocytosed polyamines into the cytosol where polyamines can be metabolized by serum amine oxidases into 3-aminopropanal, a reactive aminoaldehyde. 3-aminopropanal also undergoes spontaneous decomposition to acrolein, a well-known reactive aldehyde carcinogen. Finding that the loss of ATP13A3 rescues that FANCD2-/-ALDH9A1-/- cells indicates that 3-aminopropanal and/or acrolein induces endogenous DNA damage requiring the Fanconi anemia pathway function for repair. Finally, to determine the contribution of ALDH9A1 variants to clinical manifestations of FA patients, we performed targeted sequencing of DNA from FA patients. We identified five missense variants, four of which had high CADD scores (>20). ALDH9A1 cDNA containing missense variants with high CADD scores expressed in ALDH9A1-/- Jurkat cells resulted in lower protein expression than the WT cDNA. Cell culture supernatant from cells expressing the variant cDNAs also had increased aldehyde levels as assessed by fluorometric assays, suggesting decreased enzymatic activity of the variant proteins. The patients with ALDH9A1 missense variants with high CADD scores had either early hematologic onset of FA (n=3; two patients before age 1 and one patient before age 4) or AML (n=1). In conclusion, we showed that the loss of ALDH9A1 generates endogenous DNA damage necessitating the FA pathway for its repair. Synthetic lethality caused by the combined loss of FANCD2 and ALDH9A1 was rescued by the loss of ATP13A3, which suggests that 3-aminopropanal is the culprit aminoaldehyde that accumulates in ALDH9A1-deficient cells and results in DNA damage. Functionally deleterious ALDH9A1 variants were observed in some FA patients with early onset of disease suggesting that ALDH9A1 could be a modifier of FA in humans. Disclosures Sridhar: Deciphera Pharmaceuticals: Current Employment; CRISPR Therapeutics: Ended employment in the past 24 months. White: Regeneron Pharmaceuticals: Current Employment. Smogorzewska: Rocket Pharmaceuticals: Research Funding.

TRF1 poly(ADP-ribosyl)ation by PARP1 allows proper telomere replication through helicase recruitment in non-ALT cells

Telomeres are nucleoprotein structures at eukaryotic chromosome termini. Their stability is preserved by a six-protein complex named shelterin. Among these, TRF1 binds telomere duplex and assists DNA replication with mechanisms only partly clarified. Poly (ADP-ribose) polymerase 1 (PARP1) is a chromatin associated enzyme which adds poly (ADP-ribose) polymers (PARs) to acceptor proteins by covalent hetero-modification. Here we found that TRF1 is covalently PARylated by PARP1 during DNA synthesis. PARP1 downregulation perturbs bromodeoxyuridine incorporation at telomeres in S-phase, triggering replication-dependent DNA damage and telomere fragility. PARylated TRF1 recruits WRN and BLM helicases in S-phase in a PARP1-dependent manner, probably through non-covalent PAR binding to solve secondary structures during telomere replication. ALT telomeres are less affected by PARP1 downregulation and are less sensitive to PARP inhibitors. This work unveils an unprecedented role for PARP1 as a "surveillant" of telomere replication, in absence of exogenous DNA insults, which orchestrates protein dynamics at proceeding replication fork.

Arabidopsis thaliana PrimPol is a primase and lesion bypass DNA polymerase with the biochemical characteristics to cope with DNA damage in the nucleus, mitochondria, and chloroplast

PrimPol is a novel Primase–Polymerase that synthesizes RNA and DNA primers de novo and extents from these primers as a DNA polymerase. Animal PrimPol is involved in nuclear and mitochondrial DNA replication by virtue of its translesion DNA synthesis (TLS) and repriming activities. Here we report that the plant model Arabidopsis thaliana encodes a functional PrimPol (AtPrimPol). AtPrimPol is a low fidelity and a TLS polymerase capable to bypass DNA lesions, like thymine glycol and abasic sites, by incorporating directly across these lesions or by skipping them. AtPrimPol is also an efficient primase that preferentially recognizes the single-stranded 3′-GTCG-5′ DNA sequence, where the 3′-G is cryptic. AtPrimPol is the first DNA polymerase that localizes in three cellular compartments: nucleus, mitochondria, and chloroplast. In vitro, AtPrimPol synthesizes primers that are extended by the plant organellar DNA polymerases and this reaction is regulated by organellar single-stranded binding proteins. Given the constant exposure of plants to endogenous and exogenous DNA-damaging agents and the enzymatic capabilities of lesion bypass and re-priming of AtPrimPol, we postulate a predominant role of this enzyme in avoiding replication fork collapse in all three plant genomes, both as a primase and as a TLS polymerase.

hSSB2 (NABP1) is required for the recruitment of RPA during the cellular response to DNA UV damage

Maintenance of genomic stability is critical to prevent diseases such as cancer. As such, eukaryotic cells have multiple pathways to efficiently detect, signal and repair DNA damage. One common form of exogenous DNA damage comes from ultraviolet B (UVB) radiation. UVB generates cyclobutane pyrimidine dimers (CPD) that must be rapidly detected and repaired to maintain the genetic code. The nucleotide excision repair (NER) pathway is the main repair system for this type of DNA damage. Here, we determined the role of the human Single-Stranded DNA Binding protein 2, hSSB2, in the response to UVB exposure. We demonstrate that hSSB2 levels increase in vitro and in vivo after UVB irradiation and that hSSB2 rapidly binds to chromatin. Depletion of hSSB2 results in significantly decreased Replication Protein A (RPA32) phosphorylation and impaired RPA32 localisation to the site of UV-induced DNA damage. Delayed recruitment of NER protein Xeroderma Pigmentosum group C (XPC) was also observed, leading to increased cellular sensitivity to UVB. Finally, hSSB2 was shown to have affinity for single-strand DNA containing a single CPD and for duplex DNA with a two-base mismatch mimicking a CPD moiety. Altogether our data demonstrate that hSSB2 is involved in the cellular response to UV exposure.