The study of the association between genotype and phenotypic manifestations of the Huntington’s chorea pathogenesis

Direct molecular-genetic analysis of the region containing CAG and CCG repeats of the IT15 gene from 37 patients with the clinical diagnosis of Huntington’s chorea was carried out. The allele with the expansion of CAG repeats in the state of heterozygosity was found in 33 patients; DNA analysis did not confirm a clinical diagnosis in four cases. Twenty probable asymptomatic carriers were examined; 11 of them inherited a mutant chromosome. A disequilibrium in the linkage between the (CGG)₁₀ allele and the alleles with the expansion of CAG repeats in the IT15 gene in a group of patients from Ukraine was found. Significant differences in character of instability of CAG repeats that depends on paternal or maternal inheritance were revealed. The genetic factors that are associated with age variability of onset of the disease were studied.     

Genetic diversity of <Emphasis Type="Italic">avenin-like b</Emphasis> genes in <Emphasis Type="Italic">Aegilops tauschii</Emphasis> Coss

Avenin-like storage proteins influence the rheological properties and processing quality in common wheat, and the discovery of new alleles will benefit wheat quality improvement. In this study, 13 avenin-like b alleles (TaALPb7D-A–M) were discovered in 108 Aegilops tauschii Coss. accessions. Ten alleles were reported for the first time, while the remaining three alleles were the same as alleles in other species. A total of 15 nucleotide changes were detected in the 13 alleles, resulting in only 11 amino acid changes because of synonymous mutations. Alleles TaALPb7D-E, TaALPb7D-G, and TaALPb7D-J encoded the same protein. These polymorphic sites existed in the N-terminus, Repetitive region (Left), Repetitive region (Right) and C-terminus domains, with no polymorphisms in the signal peptide sequence nor in those encoding the 18 conserved cysteine residues. Phylogenetic analysis divided the TaALPb7Ds into four clades. The Ae. tauschii alleles were distributed in all four clades, while the alleles derived from common wheat, TaALPb7D-G and TaALPb7D-C, belonged to clade III and IV, respectively. Alleles TaALPb7D-G and TaALPb7D-C were the most widely distributed, being present in nine and six countries, respectively. Iran and Turkey exhibited the highest genetic diversity with respect to TaALPb7D alleles, accessions from these countries carrying seven and six alleles, respectively, which implied that these countries were the centers of origin of the avenin-like b gene. The new alleles discovered and the phylogenetic analysis of avenin-like b genes will provide breeding materials and a theoretical basis for wheat quality improvement.     

Potential Transfer of Polyglutamine and CAG-Repeat RNA in Extracellular Vesicles in Huntington’s Disease: Background and Evaluation in Cell Culture

In Huntington’s disease (HD) the imperfect expanded CAG repeat in the first exon of the HTT gene leads to the generation of a polyglutamine (polyQ) protein, which has some neuronal toxicity, potentially mollified by formation of aggregates. Accumulated research, reviewed here, implicates both the polyQ protein and the expanded repeat RNA in causing toxicity leading to neurodegeneration in HD. Different theories have emerged as to how the neurodegeneration spreads throughout the brain, with one possibility being the transport of toxic protein and RNA in extracellular vesicles (EVs). Most cell types in the brain release EVs and these have been shown to contain neurodegenerative proteins in the case of prion protein and amyloid-beta peptide. In this study, we used a model culture system with an overexpression of HTT-exon 1 polyQ-GFP constructs in human 293T cells and found that the EVs did incorporate both the polyQ-GFP protein and expanded repeat RNA. Striatal mouse neural cells were able to take up these EVs with a consequent increase in the green fluorescent protein (GFP) and polyQ-GFP RNAs, but with no evidence of uptake of polyQ-GFP protein or any apparent toxicity, at least over a relatively short period of exposure. A differentiated striatal cell line expressing endogenous levels of Hdh mRNA containing the expanded repeat incorporated more of this mRNA into EVs as compared to similar cells expressing this mRNA with a normal repeat length. These findings support the potential of EVs to deliver toxic expanded trinucleotide repeat RNAs from one cell to another, but further work will be needed to evaluate potential EV and cell-type specificity of transfer and effects of long-term exposure. It seems likely that expanded HD-associated repeat RNA may appear in biofluids and may have use as biomarkers of disease state and response to therapy.     

Quantification of age-dependent somatic CAG repeat instability in Hdh CAG knock-in mice reveals different expansion dynamics in striatum and liver

Background

Age at onset of Huntington''s disease (HD) is largely determined by the CAG trinucleotide repeat length in the HTT gene. Importantly, the CAG repeat undergoes tissue-specific somatic instability, prevalent in brain regions that are disease targets, suggesting a potential role for somatic CAG repeat instability in modifying HD pathogenesis. Thus, understanding underlying mechanisms of somatic CAG repeat instability may lead to discoveries of novel therapeutics for HD. Investigation of the dynamics of the CAG repeat size changes over time may provide insights into the mechanisms underlying CAG repeat instability.

Methodology/Principal Findings

To understand how the HTT CAG repeat length changes over time, we quantified somatic instability of the CAG repeat in Huntington''s disease CAG knock-in mice from 2–16 months of age in liver, striatum, spleen and tail. The HTT CAG repeat in spleen and tail was very stable, but that in liver and striatum expanded over time at an average rate of one CAG per month. Interestingly, the patterns of repeat instability were different between liver and striatum. Unstable CAG repeats in liver repeatedly gained similar sizes of additional CAG repeats (approximately two CAGs per month), maintaining a distinct population of unstable repeats. In contrast, unstable CAG repeats in striatum gained additional repeats with different sizes resulting in broadly distributed unstable CAG repeats. Expanded CAG repeats in the liver were highly enriched in polyploid hepatocytes, suggesting that the pattern of liver instability may reflect the restriction of the unstable repeats to a unique cell type.

Conclusions/Significance

Our results are consistent with repeat expansion occurring as a consequence of recurrent small repeat insertions that differ in different tissues. Investigation of the specific mechanisms that underlie liver and striatal instability will contribute to our understanding of the relationship between instability and disease and the means to intervene in this process.     

Diversity of <Emphasis Type="Italic">A</Emphasis> mating type in <Emphasis Type="Italic">Lentinula edodes</Emphasis> and mating type preference in the cultivated strains

Diversity of A mating type in Lentinula edodes has been assessed by analysis of A mating loci in 127 strains collected from East Asia. It was discovered that hypervariable sequence region with an approximate length of 1 kb in the A mating locus, spanning 5′ region of HD2-intergenic region-5′ region of HD1, could represent individual A mating type as evidenced by comprehensive mating analysis. The sequence analysis revealed 27 A mating type alleles from 96 cultivated strains and 48 alleles from 31 wild strains. Twelve of them commonly appeared, leaving 63 unique A mating type alleles. It was also revealed that only A few A mating type alleles such as A1, A4, A5, and A7 were prevalent in the cultivated strains, accounting for 62.5% of all A mating types. This implies preferred selection of certain A mating types in the process of strain development and suggests potential role of A mating genes in the expression of genes governing mushroom quality. Dominant expression of an A mating gene HD1 was observed from A1 mating locus, the most prevalent A allele, in A1-containing dikaryons. However, connections between HD1 expression and A1 preference in the cultivated strains remain to be verified. The A mating type was highly diverse in the wild strains. Thirty-six unique A alleles were discovered from relatively small and confined area of mountainous region in Korean peninsula. The number will further increase because no A allele has been recurrently observed in the wild strains and thus newly discovered strain will have good chances to contain new A allele. The high diversity in small area also suggests that the A mating locus has evolved rapidly and thus its diversity will further increase.     

Comparison of alleles at the <Emphasis Type="Italic">Gli-1</Emphasis> loci of common wheat by means of two-dimensional electrophoresis of gliadin and RFLP analysis

Allelic variants of the Gli-1 locus is known to control groups (blocks) of gliadin polypeptides (gliadins). Some allelic variants of blocks that differ in the electrophoretic (acid gel) mobility (EM) of only one gliadin of the block were compared using two-dimensional electrophoresis (SDS-PAGE) and the RFLP procedure. It was found that, in these pairs of similar alleles (Gli-B1f, Gli-B1s, and Gli-D1a as compared with Gli-B1e, Gli-B1n, and Gli-D1c, respectively), faster γ-gliadin had smaller molecular weight (MW). Alleles at the Gli-A1 locus (Gli-A1j, Gli-A1i, Gli-A1a, Gli-A1k, and Gli-A1f) differ in the EM of the γ-gliadin so that Gli-A1j controls the slowest γ-gliadin and Gli-A1f controls the fastest one. We found that, in this order of alleles, faster γ-gliadin always had smaller MW. It was suggested that similar alleles might arise from one another by spontaneous mutations changing the number of repeating sequences or length of the polyglutamine domain present in the γ-gliadin gene thereby influencing MW and EM of encoding polypeptide. Other mechanisms of the mutational appearance of new alleles were found earlier by comparison of allele pairs: Gli-D1a and Gli-D1k (gene silencing) and Gli-D1b and Gli-D1d (gene amplification). We discovered contrasting families of alleles at the Gli-B1 and at the Gli-D1 loci and also two variants of apparently the same allele Gli-D1a that differed in the number of encoded ω-gliadins. Families of alleles at one locus of T. aestivum might inherit from different genotypes of corresponding diploid donor, as we suggested earlier.     

Association between the length of the <Emphasis Type="Italic">MUC8-</Emphasis>minisatellite 5 region and susceptibility to chronic obstructive pulmonary disease (COPD)

In asthma and chronic obstructive pulmonary disease (COPD), mucins display disease-related alterations caused by airway mucus obstruction. MUC5AC, MUC5B and MUC8 are known as the major secretory mucins in human airway epithelial cells. Analysis of mucin genes has identified the presence of several features with a variable number of tandem repeats (VNTR; minisatellites) in the central region of each mucin. In our previous study, six minisatellites in the region of the MUC8 gene were identified, and the MUC8-MS5 minisatellite showed the highest heterozygosity among them. In this study, we evaluated the relationship between MUC8-MS5 and susceptibility to asthma and COPD. A case-control study was performed with 229 controls, 123 COPD cases and 77 asthma cases. A significant association (OR 3.96) between short alleles (2/2 repeats) and the occurrence of COPD was observed [95% confidence interval (CI) 1.32–11.88; p?=?0.008]. Hence, the increased frequency of 2/2 homo-short alleles were also found in asthma cases (3.11; CI 0.88–11.05; p?=?0.066), though this association was not statistically significant. These results revealed a genetic association between MUC8 and COPD, and that the specific short minisatellite alleles (2/2) of MUC8-MS5 may be a risk factor for COPD.     

Azadiradione Restores Protein Quality Control and Ameliorates the Disease Pathogenesis in a Mouse Model of Huntington’s Disease

Huntington’s disease (HD) is an autosomal dominantly inherited neurodegenerative disorder caused by expansion of CAG repeats in the coding area of huntingtin gene. In the HD brain, mutant huntingtin protein goes through proteolysis, and its amino-terminal portion consisting of polyglutamine repeats accumulate as inclusions that result in progressive impairment of cellular protein quality control system. Here, we demonstrate that partial rescue of the defective protein quality control in HD model mouse by azadiradione (a bioactive limonoids found in the seed of Azadirachta indica) could potentially improve the disease pathology. Prolonged treatment of azadiradione to HD mice significantly improved the progressive deterioration in body weight, motor functioning along with extension of lifespan. Azadiradione-treated HD mice brain also exhibited considerable decrease in mutant huntingtin aggregates load and improvement of striatal pathology in comparison with age-matched saline-treated HD controls. Biochemical analysis further revealed upregulation and activation of not only HSF1 (master regulator of protein folding) but also Ube3a (an ubiquitin ligase involved in the clearance of mutant huntingtin) in azadiradione-treated mice. Our results indicate that azadiradione-mediated enhanced folding and clearance of mutant huntingtin might underlie improved disease pathology in HD mice and suggests that it could be a potential therapeutic molecule to delay the progression of HD.     

Marker-assisted pyramiding of <Emphasis Type="BoldItalic">Thinopyrum-</Emphasis>derived leaf rust resistance genes <Emphasis Type="BoldItalic">Lr19</Emphasis> and <Emphasis Type="BoldItalic">Lr24</Emphasis> in bread wheat variety HD2733

This study was undertaken to pyramid two effective leaf rust resistance genes (Lr19 and Lr24) derived from Thinopyrum (syn. Agropyron), in the susceptible, but agronomically superior wheat cultivar HD2733 using marker-assisted selection. In the year 2001, HD2733 was released for irrigated timely sown conditions of the north eastern plains zone (NEPZ) of India became susceptible to leaf rust, a major disease of the region. Background selection helped in developing near-isogenic lines (NILs) of HD2733 with Lr19 and Lr24 with 97.27 and \(98.94\%\), respectively, of genomic similarity with the parent cultivar, after two backcrossing and one generation of selfing. NILs were intercrossed to combine the genes Lr19 and Lr24. The combination of these two genes in the cultivar HD2733 is expected to provide durable leaf rust resistance in farmers’ fields.     

Analysis of Polymorphic Variants of Gene <Emphasis Type="Italic">GIPC1</Emphasis> CGG Repeats in Healthy Individuals and in Patients with Breast Cancer and Non-Small Cell Lung Cancer

The GIPC1 gene product promotes clustering of some transmembrane receptors, including those involved in carcinogenesis, and protects them against ubiquitin-dependent degradation. The 5′ untranslated region of GIPC1 contains a polymorphic trinucleotide CGG repeat, which has not been characterized earlier. In the present study, we have carried out comparative analysis of the allele and genotype frequencies of this repeat in 129 samples of breast cancer (BC), 58 samples of non-small cell lung cancer (NSCLC), and 215 samples of healthy donors. The CGG repeat in the 5′ untranslated GIPC1 gene region was shown to be highly polymorphic and represented by at least eight alleles. Alleles CGG_10–13 were major, occurring at frequencies of 22, 41, 27, and 9%, respectively; the total frequency of the remaining alleles was approximately 1%. Heterozygosity of the CGG repeat was 0.70. Allele CGG ₁₂ was shown to be associated with high risk of developing NSCLC (α = 0.05).     

SSR-based molecular profiling of 237 persimmon (<Emphasis Type="Italic">Diospyros kaki</Emphasis> Thunb.) germplasms using an <Emphasis Type="Italic">ASTRINGENCY</Emphasis>-linked marker

Pollination-constant non-astringent (PCNA) trait is desirable in persimmon production because it confers natural astringency loss in mature persimmon fruit. Expression of the PCNA trait requires six homozygous recessive PCNA (ast) alleles at the single ASTRINGENCY (AST) locus in hexaploid persimmon. When crossing non-PCNA accessions to breed PCNA offspring, knowledge of ast and non-PCNA (AST) allele dosage in the parental accessions is important, because more PCNA offspring can segregate from a non-PCNA parent with more ast and fewer AST alleles. Previously, we have demonstrated that a region linked to the AST locus has numerous fragment size polymorphisms with varying numbers of simple sequence repeats. Here, we reveal the polymorphisms in this region in a broad collection of persimmon germplasms. Among 237 accessions, we distinguished 21 AST- and 5 ast-linked fragments with different sizes. Based on the number of fragments detected per individual, we identified 21 non-PCNA accessions with three different ast alleles; by crossing these with a PCNA parent, we obtain PCNA offspring under autohexaploid inheritance. Furthermore, AST and ast allelic combination patterns in hexaploid persimmon were shown to be applicable to cultivar identification of non-PCNA accessions. We directly sequenced ast-linked fragments from 48 accessions with one-size peak of ast-linked fragment and found two distinctive groups of fragments based on single nucleotide polymorphisms. This result suggests that a bottleneck event occurred during ast allele development. We conclude that our fragment size profile can be used to accelerate PCNA breeding that uses non-PCNA parents and to study ast allele accumulation in persimmon.     

Interactive effects of multiple vernalization (<Emphasis Type="Italic">Vrn-1</Emphasis>)- and photoperiod (<Emphasis Type="Italic">Ppd-1</Emphasis>)-related genes on the growth habit of bread wheat and their association with heading and flowering time

Background

The precise identification of Winterness/Springness (growth habit) for bread wheat, which is determined by genes involved in vernalization and photoperiod, will contribute to the effective utilization of bread wheat varieties. Here, 198 varieties from the Yellow and Huai wheat production region (YHW) in China were collected to identify their vernalization (Vrn-1) and photoperiod (Ppd-1) gene composition via a series of functional markers and their association with vernalization and photoperiod requirements at three locations during two years of experiments. The growth habits were measured during the spring sowing season.

Results

The results showed that the semi-winter varieties (grades1–4) were most prevalent in the population. The relative effects of single Vrn alleles on the growth period, such as heading date (HD) and/or flowering date (FD), were as follows: Vrn-B1b?>?Vrn-B1a?>?Vrn-D1b?>?Vrn-D1a?>?vrn-D1?=?vrn-B1. The interactive effects of Vrn-B1 and Vrn-D1 on HD and FD were identical to those of Vrn-B1b. Approximately 35.3% of the cultivars carried Ppd-B1a (photoperiod-insensitive) and exhibited the earliest HD and FD. The Ppd-D1a-insensitive allele (Hapl II) was carried by just 0.5% of the varieties; however, the other two sensitive alleles were present at a higher frequency, and their effects were slightly weaker than those of Ppd-B1a. In addition, strong interactive effects between Ppd-B1 and Ppd-D1 were detected. In terms of mean values among various genotypes, the effects followed the order of Vrn-1?>?Ppd-1.

Conclusions

According to the results of ANOVA and least significant range (LSR) tests, we can conclude that Vrn-1 rather than Ppd-1 played a major role in controlling vernalization and photoperiod responses in this region. This research will be helpful for precisely characterizing and evaluating the HD, FD and even growth habit of varieties in the YHW at molecular levels.

     

Combination of newly developed SNP and InDel markers for genotyping the <Emphasis Type="Italic">Cf-9</Emphasis> locus conferring disease resistance to leaf mold disease in the tomato

The Cf-9 gene in the tomato is known to confer resistance against leaf mold disease caused by Cladosporium fulvum, and a gene-based marker targeted to the Cf-9 allele has been widely used as a crop protection approach. However, we found this marker to be misleading in genotyping. Therefore, we developed new single-nucleotide polymorphism (SNP) and insertion and deletion (InDel) markers targeted to the Cf-9 allele in order to increase genotyping accuracy and facilitate high-throughput screening. The DNA sequences of reported Cf-9, cf-9, Cf-0, and closely related Cf-4 alleles were compared, and two functional and non-synonymous SNPs were found to distinguish the Cf-9 resistance allele from the cf-9, Cf-0, and Cf-4 alleles. An SNP marker including these two SNPs was developed and applied to the genotyping of 33 tomato cultivars by high-resolution melting analysis. Our SNP marker was able to select all three Cf-9 genotypes (resistant, heterozygous, and susceptible alleles). Interestingly, two cultivars were grouped separately from these three genotypes. To further examine this outgroup, we preformed polymerase chain reaction (PCR) on two InDel regions identified by sequence comparison of the Cf-9 and Cf-4 genes. The band patterns revealed that these two cultivars carried Cf-4 rather than Cf-9 alleles and that three cultivars classified in the Cf-9 resistance group actually carried both Cf-9 and Cf-4 genes. To determine whether these genotyping results were consistent with disease resistance phenotypes, we examined the induction of a hypersensitive response by transiently expressing the corresponding effector genes, and found that the results matched perfectly with the genotyping results. These findings indicate that the combination of our SNP and InDel markers allows resistant Cf-9 alleles to be distinguished from cf-9 and Cf-4 alleles, which will be useful for marker-assisted selection of tomato cultivars resistant to C. fulvum.     

Current state of the genetic polymorphism in spring barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) from Russia assessed by the alleles of hordein-coding loci

Starch gel electrophoresis was performed to study the polymorphism of hordeins encoded by the Hrd A, Hrd B, and Hrd F loci in 211 varieties of spring barley. For 41 of these varieties, the genetic formulas were established for the first time. In the two samples of varieties, the comparative analysis of allelic diversity and allele frequencies of hordein-coding loci was carried out. The first sample consisted of 101 spring barley varieties approved for the use on the territory of the Russian Federation in 1999, while the second sample included 160 spring barley varieties that were approved in 2014; 49 of these varieties were common for both samples. It is demonstrated that the current tendency to reduction of the proportion of heterogeneous spring barley varieties is mainly due to the introduction of foreign varieties homogeneous for the hordein-coding loci. At the same time, there is an increase in polymorphism of hordein-coding loci in modern spring barley varieties. The number of alleles for the Hrd A locus increased by five alleles, and for the Hrd B locus, by nine alleles. Along with the alleles recorded earlier in barley landrace populations and varieties bred in 20th century, three novel alleles of the Hrd A locus and four alleles of the Hrd B locus were identified. The number of alleles of the Hrd F locus remained unchanged (four), and the changes in their frequencies were small. At the same time, the changes in frequency observed for some alleles of the Hrd A and Hrd B loci were statistically significant. All newly identified alleles of hordein-coding loci were found with low frequencies (from 0.003 to 0.006), so despite the increased number of alleles, no statistically significant increase in genetic diversity in terms of μ and PIC indices was observed.