曲阜地区孔姓人群17个Y-STR基因座遗传多态性分析

应用AmpFLSTR~Y-filer~(TM)PCR Amplification Kit荧光标记复合扩增试剂盒(ABI公司),对曲阜地区11 18名孔姓男性个体血样DNA进行PCR,扩增,统计分析17个Y-STR基因座的遗传学参数。实验结果显示,17个基因座除DYS385a/b基因座检出51个单倍型外,其余基因座上分别检出4~11种等位基因,等位基因频率分布在0.0009~0.8265之间。由17个基因座组成的YH单倍型系统共检出206种单倍型。根据Y-STR单倍型推断了Y-SNP单倍群,发现曲阜孔姓有3种高频单倍群:C3、Q1a1和O3,前两者有着明显的单祖先扩散结构,最可能是孔子类型。本实验通过对曲阜地区孔姓人群群体17个Y染色体短串联重复序列基因座遗传多态性的调查,记录、保存孔姓人群遗传学数据。     

PIDD4, a novel PIDD isoform without the LRR domain, can independently induce cell apoptosis in cytoplasm

PIDD1 (P53-induced death domain) is a pro-apoptotic gene which can be induced by p53. So far, three alternative splicing products of human PIDD gene have been identified. Here we report a new splicing variant of this gene and named it PIDD4. The coding sequence of PIDD4 contains intron 3 and a 60 bp insert at the 5′ of exon 3. Each insertion has an in-frame stop codon, which makes PIDD4 get translated from exon 5 then. Therefore, PIDD4 protein lacks the 32 KD N-terminal peptide, missing the LRR domain found in the other three isoforms. In this study, we have shown that the expression of PIDD4 is also regulated by p53, and as PIDD2, it is not expressed in heart either. Moreover, PIDD4 is the only isoform which is expressed in skeletal muscle. This isoform mainly localizes in the cytoplasm, and produces a relatively higher proportion of PIDD-CC fragment. Overexpression of PIDD4 independently promotes apoptosis.     

The tyrosine‐sulfated peptide receptors PSKR1 and PSY1R modify the immunity of Arabidopsis to biotrophic and necrotrophic pathogens in an antagonistic manner

The tyrosine‐sulfated peptides PSKα and PSY1 bind to specific leucine‐rich repeat surface receptor kinases and control cell proliferation in plants. In a reverse genetic screen, we identified the phytosulfokine (PSK) receptor PSKR1 as an important component of plant defense. Multiple independent loss‐of‐function mutants in PSKR1 are more resistant to biotrophic bacteria, show enhanced pathogen‐associated molecular pattern responses and less lesion formation after infection with the bacterial pathogen Pseudomonas syringae pv. tomato DC3000. By contrast, pskr1 mutants are more susceptible to necrotrophic fungal infection with Alternaria brassicicola, show more lesion formation and fungal growth which is not observed on wild‐type plants. The antagonistic effect on biotrophic and necrotrophic pathogen resistance is reflected by enhanced salicylate and reduced jasmonate responses in the mutants, suggesting that PSKR1 suppresses salicylate‐dependent defense responses. Detailed analysis of single and multiple mutations in the three paralogous genes PSKR1, ‐2 and PSY1‐receptor (PSY1R) determined that PSKR1 and PSY1R, but not PSKR2, have a partially redundant effect on plant immunity. In animals and plants, peptide sulfation is catalyzed by a tyrosylprotein sulfotransferase (TPST). Mutants lacking TPST show increased resistance to bacterial infection and increased susceptibility to fungal infection, mimicking the triple receptor mutant phenotypes. Feeding experiments with PSKα in tpst‐1 mutants partially restore the defense‐related phenotypes, indicating that perception of the PSKα peptide has a direct effect on plant defense. These results suggest that the PSKR subfamily integrates growth‐promoting and defense signals mediated by sulfated peptides and modulates cellular plasticity to allow flexible adjustment to environmental changes.     

THE ROLE OF ZINC FINGER PROTEIN IN RNAi INTERFERENCE IN A UNICELLULAR GREEN ALGA CHLAMYDOMONAS REINHARDTII (CHLOROPHYCEAE)

In our previous study, we generated a strain of 19‐P (1030) in which artificial RNA interference (RNAi) was induced by transcribing a hairpin RNA of ~780‐bp stem. We utilized this RNAi‐induced strain to uncover RNAi‐related genes. Random insertional mutagenesis was performed to generate tag‐mutants that show a RNAi deficient phenotype. The 92‐12C is one such tag‐mutant, which bears a 14‐kb deletion in chromosome 1. Complementation of 92‐12C revealed that a protein gene, including a Cys‐Cys‐Cys‐His‐type zinc finger motif and an ankyrin repeat motif, is essential for effective RNAi in Chlamydomonas reinhardtii (Dangeard). BLAST analysis revealed that the zinc finger protein is homologous to an mRNA splicing‐related protein of other species. Therefore, one of the probable scenarios is that mRNA coding for RNAi‐related proteins cannot be properly spliced, which causes RNAi deficiency in the 92‐12C tag‐mutant.     

Dexamethasone regulates expression of BRUCE/Apollon and the proliferation of neural progenitor cells

Glucocorticoid hormones (GHs) regulate cell proliferation of neural progenitor cells (NPCs) contributing to reduction of neurogenesis after stress. We show here that dexamethasone (Dex) decreases BRUCE/Apollon (BRUCE) in cultured NPCs in a GH-receptor-dependent manner. Downregulation of BRUCE by Dex or using silencing RNA reduced the number of proliferating NPCs, whilst overexpression of BRUCE counteracted the effect of Dex. Dex also elevated the deubiquitinating enzyme, Usp8/Ubpy, which via Nrdp1 decreases BRUCE. The results show that BRUCE is a target for GHs in the NPCs, and that BRUCE controls cell division of NPCs and possibly of other stem cells.

Structured summary

MINT-7148564: Nrdp1 (uniprotkb:Q8BH75) physically interacts (MI:0914) with BRUCE (uniprotkb:O88738) by anti bait co-immunoprecipitation (MI:0006)MINT-7148555: Nrdp1 (uniprotkb:Q8BH75) physically interacts (MI:0914) with Usp8 (uniprotkb:Q80U87) by anti bait co-immunoprecipitation (MI:0006)     

Genetic diversity and origin of weedy rice (Oryza sativa f. spontanea) populations found in North-eastern China revealed by simple sequence repeat (SSR) markers

BACKGROUND AND AIMS: Weedy rice (Oryza sativa f. spontanea) is one of the most notorious weeds occurring in rice-planting areas worldwide. The objectives of this study are to determine the genetic diversity and differentiation of weedy rice populations from Liaoning Province in North-eastern China and to explore the possible origin of these weedy populations by comparing their genetic relationships with rice varieties (O. sativa) and wild rice (O. rufipogon) from different sources. METHODS: Simple sequence repeat (SSR) markers were used to estimate the genetic diversity of 30 weedy rice populations from Liaoning, each containing about 30 individuals, selected rice varieties and wild O. rufipogon. Genetic differentiation and the relationships of weedy rice populations were analysed using cluster analysis (UPGMA) and principle component analysis (PCA). KEY RESULTS: The overall genetic diversity of weedy rice populations from Liaoning was relatively high (H(e) = 0.313, I = 0.572), with about 35 % of the genetic variation found among regions. The Liaoning weedy rice populations were closely related to rice varieties from Liaoning and japonica varieties from other regions but distantly related to indica rice varieties and wild O. rufipogon. CONCLUSIONS: Weedy rice populations from Liaoning are considerably variable genetically and most probably originated from Liaoning rice varieties by mutation and intervarietal hybrids. Recent changes in farming practices and cultivation methods along with less weed management may have promoted the re-emergence and divergence of weedy rice in North-eastern China.     

The porphyrin TMPyP4 inhibits elongation during the noncanonical translation of the FTLD/ALS-associated GGGGCC repeat in the C9orf72 gene

GGGGCC (G₄C₂) repeat expansion in the C9orf72 gene has been shown to cause frontotemporal lobar degeneration and amyotrophic lateral sclerosis. Dipeptide repeat proteins produced through repeat-associated non-AUG (RAN) translation are recognized as potential drivers for neurodegeneration. Therefore, selective inhibition of RAN translation could be a therapeutic avenue to treat these neurodegenerative diseases. It was previously known that the porphyrin TMPyP4 binds to G₄C₂ repeat RNA. However, the consequences of this interaction have not been well characterized. Here, we confirmed that TMPyP4 inhibits C9orf72 G₄C₂ repeat translation in cellular and in in vitro translation systems. An artificial insertion of an AUG codon failed to cancel the translation inhibition, suggesting that TMPyP4 acts downstream of non-AUG translation initiation. Polysome profiling assays also revealed polysome retention on G₄C₂ repeat RNA, along with inhibition of translation, indicating that elongating ribosomes stall on G₄C₂ repeat RNA. Urea-resistant interaction between G₄C₂ repeat RNA and TMPyP4 likely contributes to this ribosome stalling and thus to selective inhibition of RAN translation. Taken together, our data reveal a novel mode of action of TMPyP4 as an inhibitor of G₄C₂ repeat translation elongation.     

Mapping of a Wheat Resistance Gene to Yellow Mosaic Disease by Amplified Fragment Length Polymorphism and Simple Sequence Repeat Markers

Wheat （Triticum aestivum L.） yellow mosaic virus （WYMV） is transmitted by a fungal vector through soil and causes serious wheat yield losses due to yellow mosaic disease, with yellow-streaked leaves and stunted plants. In the present study, the amplified fragment length polymorphisms （AFLP） and simple sequence repeat （SSR） were used to identify the molecular linkages with the resistance gene against WYMV. Bulked segregant analysis was performed with an F2 population derived from the cross of cultivar Ningmai 9 （resistant） × cultivar Yangmai 10 （susceptible）. By screening among the resistant or susceptible parents, the F2 pools and the individuals in the F2 population with 64 combined selective AFLP primers （EcoRI/MseI） or 290 reported SSR primers, a polymorphic DNA segment （approximately 120 bp） was amplified using the primer pair E2/M5, and an SSR marker （approximately 180 bp） was located on wheat chromosome 2A using the primer Xgwm328. Analysis with MAPMAKER/Exp Version 3.0b （Whitehead institute for Biomedical Research, Cambridge, MA, USA） indicated that these two markers were dominantly associated with the resistance gene at distances of 5.4 cM or 17.6 cM, respectively. The resistance gene to WYMV derived from Ningmai 9, is temporarily named YmNM, and was mapped to wheat chromosome 2A.