Rapid and Quantitative Assay of Amyloid-Seeding Activity in Human Brains Affected with Prion Diseases

The infectious agents of the transmissible spongiform encephalopathies are composed of amyloidogenic prion protein, PrP^Sc. Real-time quaking-induced conversion can amplify very small amounts of PrP^Sc seeds in tissues/body fluids of patients or animals. Using this in vitro PrP-amyloid amplification assay, we quantitated the seeding activity of affected human brains. End-point assay using serially diluted brain homogenates of sporadic Creutzfeldt–Jakob disease patients demonstrated that 50% seeding dose (SD₅₀) is reached approximately 10¹⁰/g brain (values varies 10^8.79–10.63/g). A genetic case (GSS-P102L) yielded a similar level of seeding activity in an autopsy brain sample. The range of PrP^Sc concentrations in the samples, determined by dot-blot assay, was 0.6–5.4 μg/g brain; therefore, we estimated that 1 SD₅₀ unit was equivalent to 0.06–0.27 fg of PrP^Sc. The SD₅₀ values of the affected brains dropped more than three orders of magnitude after autoclaving at 121°C. This new method for quantitation of human prion activity provides a new way to reduce the risk of iatrogenic prion transmission.     

No Viral Association Found in a Set of Differentiated Vulvar Intraepithelial Neoplasia Cases by Human Papillomavirus and Pan-Viral Microarray Testing

Vulvar Intraepithelial Neoplasia (VIN) is the precursor lesion of Vulvar Squamous Cell Carcinoma (VSCC), and the differentiated type (dVIN) is more frequently observed in relation to VSCC. In contrast to usual-type VIN (uVIN), which is related to infection by human papillomavirus (HPV), a germline mutation in the p53 gene is thought to be associated with ~90% of dVIN cases. To date, no infectious agent has been identified in association with dVIN, and studies investigating this possibility have been hindered by the difficulty in accurately diagnosing dVIN from small biopsies. Here, we used immunostaining for p16^ink4a, a biomarker for HPV infection, to study 14 uVIN high-grade VIN and 14 dVIN cases, and to select 10 dVIN cases to broadly screen for all known viruses using a pan-viral microarray platform (ViroChip). All of the uVIN tissue samples, including 8 warty and 6 basaloid cases, showed positivity with the p16^ink4a immunostain. The staining pattern was full-thickness for all except two cases in which positive staining was localized in the lower 1/3 of the epidermis. In contrast, immunostaining for p16^ink4a was negative in all dVIN cases. ViroChip analysis of 10 pure dVIN samples confirmed the absence of human papillomavirus subtypes or any other virus with the exception of a single sample that showed a weak microarray signature to a porcine herpesvirus. Follow-up PCR testing of the sample was negative for herpesvirus, and in-depth metagenomic next-generation sequencing revealed only sequences corresponding to non-pathogenic viral flora and bacterial contamination. In this study, we demonstrated lack of a virus association in 10 dVIN cases. Alternative pathways for carcinogenesis such as the p53 mutation should be considered for investigation of potential treatment options in dVIN.     

A Novel Cell Death Gene Acts to Repair Patterning Defects in Drosophila melanogaster

Cell death is a mechanism utilized by organisms to eliminate excess cells during development. Here, we describe a novel regulator of caspase-independent cell death, Mabiki (Mabi), that is involved in the repair of the head patterning defects caused by extra copies of bicoid in Drosophila melanogaster. Mabiki functions together with caspase-dependent cell death mechanisms to provide robustness during development.     

Influence of olive-derived hydroxytyrosol on the toll-like receptor 4-dependent inflammatory response of mouse peritoneal macrophages

Macrophages play important roles in the host innate immune response and are involved in the onset of diseases caused by inflammation. Toll-like receptor 4 (TLR4)-mediated inflammatory responses of macrophages may be associated with diseases such as diabetes and diseases of the cardiovascular system. Hydroxytyrosol (HT) exerts strong antioxidant and anti-inflammatory effects and may be applied in the treatment of inflammatory diseases. In the present study conducted in vitro, we investigated the effects of the TLR4-dependent anti-inflammatory effect of HT on peritoneal macrophage of BALB/c mice. We show here that the elevated levels of iNOS gene expression and nitric oxide production induced by lipopolysaccharide (LPS) (0.25 μg/ml) were suppressed by HT (12.5 μg/ml). LPS-dependent NF-κB gene expression and phosphorylation of NF-κB were not affected by HT under these conditions. In contrast, the expression of TNF-α was significantly increased in the presence of LPS and HT. These results suggest that HT suppressed nitric oxide production by decreasing iNOS gene expression through a mechanism independent of the NF-κB signaling pathway. These novel findings suggest that the modulation by HT of the expression of genes involved in inflammation may involve multiple mechanisms.     

Srs2 Plays a Critical Role in Reversible G2 Arrest upon Chronic and Low Doses of UV Irradiation via Two Distinct Homologous Recombination-Dependent Mechanisms in Postreplication Repair-Deficient Cells

Differential posttranslational modification of proliferating cell nuclear antigen (PCNA) by ubiquitin or SUMO plays an important role in coordinating the processes of DNA replication and DNA damage tolerance. Previously it was shown that the loss of RAD6-dependent error-free postreplication repair (PRR) results in DNA damage checkpoint-mediated G₂ arrest in cells exposed to chronic low-dose UV radiation (CLUV), whereas wild-type and nucleotide excision repair-deficient cells are largely unaffected. In this study, we report that suppression of homologous recombination (HR) in PRR-deficient cells by Srs2 and PCNA sumoylation is required for checkpoint activation and checkpoint maintenance during CLUV irradiation. Cyclin-dependent kinase (CDK1)-dependent phosphorylation of Srs2 did not influence checkpoint-mediated G₂ arrest or maintenance in PRR-deficient cells but was critical for HR-dependent checkpoint recovery following release from CLUV exposure. These results indicate that Srs2 plays an important role in checkpoint-mediated reversible G₂ arrest in PRR-deficient cells via two separate HR-dependent mechanisms. The first (required to suppress HR during PRR) is regulated by PCNA sumoylation, whereas the second (required for HR-dependent recovery following CLUV exposure) is regulated by CDK1-dependent phosphorylation.DNA damage occurs frequently in all organisms as a consequence of both endogenous metabolic processes and exogenous DNA-damaging agents. In nature, the steady-state level of DNA damage is usually very low. However, chronic low-level DNA damage can lead to age-related genome instability as a consequence of the accumulation of DNA damage (12, 27). Increasing evidence implicates DNA damage-related replication stress in genome instability (7, 21). Replication stress occurs when an active fork encounters DNA lesions or proteins tightly bound to DNA. These obstacles pose a threat to the integrity of the replication fork and are thus a potential source of genome instability, which can contribute to tumorigenesis and aging in humans (4, 11). Confronted with this risk, cells have developed fundamental DNA damage response mechanisms in order to faithfully complete DNA replication (8).In budding yeast Saccharomyces cerevisiae, the Rad6-dependent postreplication repair (PRR) pathway is subdivided into three subpathways, which allow replication to resume by bypassing the lesion without repairing the damage (3, 22, 33). Translesion synthesis (TLS) pathways dependent on the DNA polymerases eta and zeta promote error-free or mutagenic bypass depending on the DNA lesion and are activated upon monoubiquitination of proliferating cell nuclear antigen (PCNA) at Lys164 (K164) (5, 16, 37). The Rad5 (E3) and Ubc13 (E2)/Mms2 (E2 variant)-dependent pathway promotes error-free bypass by template switching and is activated by polyubiquitination of PCNA via a Lys63-linked ubiquitin chain (16, 38, 41). It remains mechanistically unclear how polyubiquitinated PCNA promotes template switching at the molecular level. In addition to its ubiquitin E3 activity, Rad5 also has a helicase domain and was recently shown to unwind and reanneal fork structures in vitro (6). This led to the proposal that Rad5 helicase activity is required at replication forks to promote fork regression and subsequent template switching. It is possible that PCNA polyubiquitination acts to facilitate Rad5-dependent template switching by inhibiting monoubiquitination-dependent TLS activity and/or by recruiting alternative proteins to the fork.In addition to modification by ubiquitin, PCNA can also be sumoylated on Lys164 by the SUMO E3 ligase Siz1 (16). A second sumoylation site, Lys127, is also targeted by an alternative SUMO E3 ligase, Siz2, albeit with lower efficiency (16, 30). PCNA SUMO modification results in recruitment of the Srs2 helicase and subsequent inhibition of Rad51-dependent recombination events (29, 32). The modification can therefore allow the replicative bypass of lesions by promoting the RAD6 pathway. Srs2 is known to act as an antirecombinase by eliminating recombination intermediates. This can occur independently of PCNA sumoylation, and when srs2Δ cells are UV irradiated or other antirecombinases, such as Sgs1, are concomitantly deleted, toxic recombination structures accumulate (1, 10). Such genetic data are consistent with the ability of Srs2 to disassemble the Rad51 nucleoprotein filaments formed on single-stranded DNA (ssDNA) in vitro (20, 40). In addition to directly inhibiting homologous recombination (HR), Srs2 is also involved in regulating HR outcomes to not produce crossover recombinants in the mitotic cell cycle (18, 34, 35).The UV spectrum present in sunlight is a primary environmental cause of exogenous DNA damage. Sunlight is a potent and ubiquitous carcinogen responsible for much of the skin cancer in humans (17). In the natural environment, organisms are exposed to chronic low-dose UV light (CLUV), as opposed to the acute high doses commonly used in laboratory experiments. Hence, understanding the cellular response to CLUV exposure is an important approach complementary to the more traditional laboratory approaches for clarifying the biological significance of specific DNA damage response pathways. A recently developed experimental assay for the analysis of CLUV-induced DNA damage responses was used to show that the PCNA polyubiquitination-dependent error-free PRR pathway plays a critical role in tolerance of CLUV exposure by preventing the generation of excessive ssDNA when replication forks arrest, thus suppressing counterproductive checkpoint activation (13).Mutants of SRS2 were first isolated by their ability to suppress the radiation sensitivity of rad6 and rad18 mutants (defective in PRR) by a mechanism that requires a functional HR pathway (23, 36). In this study, we analyzed the function of Srs2 in CLUV-exposed PRR-deficient cells. We established that Srs2 acts in conjunction with SUMO-modified PCNA to lower the threshold for checkpoint activation and maintenance by suppressing the function of HR in rad18Δ cells exposed to CLUV. We also showed that Srs2 is separately involved in an HR-dependent recovery process following cessation of CLUV exposure and that this second role for Srs2, unlike its primary role in checkpoint activation and maintenance, is regulated by CDK1-dependent phosphorylation. Thus, Srs2 is involved in both CLUV-induced checkpoint-mediated arrest and recovery from CLUV exposure in PRR-deficient cells, and these two functions, while both involving HR, are separable and thus independent.     

Identification and characterization of nuclear pore complex components in Arabidopsis thaliana

The nuclear pore complex (NPC) facilitates nucleocytoplasmic transport, a crucial process for various cellular activities. The NPC comprises ~30 nucleoporins and is well characterized in vertebrates and yeast. However, only eight plant nucleoporins have been identified, and little information is available about the complete molecular structure of plant NPCs. In this study, an interactive proteomic approach was used to identify Arabidopsis thaliana nucleoporins. A series of five cycles of interactive proteomic analysis was performed using green fluorescent protein (GFP)-tagged nucleoporins. The identified nucleoporins were then cloned and subcellular localization analyses were performed. We found that the plant NPC contains at least 30 nucleoporins, 22 of which had not been previously annotated. Surprisingly, plant nucleoporins shared a similar domain organization to their vertebrate (human) and yeast (Saccharomyces cerevisiae) counterparts. Moreover, the plant nucleoporins exhibited higher sequence homology to vertebrate nucleoporins than to yeast nucleoporins. Plant NPCs lacked seven components (NUCLEOPORIN358 [Nup358], Nup188, Nup153, Nup45, Nup37, NUCLEAR DIVISION CYCLE1, and PORE MEMBRANE PROTEIN OF 121 kD) that were present in vertebrate NPCs. However, plants possessed a nucleoporin, Nup136/Nup1, that contained Phe-Gly repeats, and sequence analysis failed to identify a vertebrate homolog for this protein. Interestingly, Nup136-GFP showed greater mobility on the nuclear envelope than did other nucleoporins, and a Nup136/Nup1 deficiency caused various defects in plant development. These findings provide valuable new information about plant NPC structure and function.     

Novel metabolic pathway for salicylate biodegradation via phenol in yeast <Emphasis Type="Italic">Trichosporon moniliiforme</Emphasis>

A novel metabolic pathway was found in the yeast Trichosporon moniliiforme WU-0401 for salicylate degradation via phenol as the key intermediate. When 20 mM salicylate was used as the sole carbon source for the growth of strain WU-0401, phenol was detected as a distinct metabolite in the culture broth. Analysis of the products derived from salicylate or phenol through reactions with resting cells and a cell-free extract of strain WU-0401 indicated that salicylate is initially decarboxylated to phenol and then oxidized to catechol, followed by aromatic ring cleavage to form cis-cis muconate.     

A missense mutation in the vacuolar protein GOLD36 causes organizational defects in the ER and aberrant protein trafficking in the plant secretory pathway

A central question in cell biology is how the identity of organelles is established and maintained. Here, we report on GOLD36, an EMS mutant identified through a screen for partial displacement of the Golgi marker, ST‐GFP, to other organelles. GOLD36 showed partial distribution of ST‐GFP into a modified endoplasmic reticulum (ER) network, which formed bulges and large skein‐like structures entangling Golgi stacks. GOLD36 showed defects in ER protein export as evidenced by our observations that, besides the partial retention of Golgi markers in the ER, the trafficking of a soluble bulk‐flow marker to the cell surface was also compromised. Using a combination of classical mapping and next‐generation DNA sequencing approaches, we linked the mutant phenotype to a missense mutation of a proline residue in position 80 to a leucine residue in a small endomembrane protein encoded by the gold36 locus ( At1g54030 ). Subcellular localization analyses indicated that GOLD36 is a vacuolar protein and that its mutated form is retained in the ER. Interestingly also, a gold36 knock‐out mutant mirrored the GOLD36 subcellular phenotype. These data indicate that GOLD36 is a protein destined to post‐ER compartments and suggest that its export from the ER is a requirement to ensure steady‐state maintenance of the organelle’s organization and functional activity in relation to other secretory compartments. We speculate that GOLD36 may be a factor that is necessary for ER integrity because of its ability to limit deleterious effects of other secretory proteins on the ER.