Clinical variability and novel mutations in the NHEJ1 gene in patients with a Nijmegen breakage syndrome‐like phenotype

We have previously shown that mutations in the genes encoding DNA Ligase IV (LIGIV) and RAD50, involved in DNA repair by nonhomologous‐end joining (NHEJ) and homologous recombination, respectively, lead to clinical and cellular features similar to those of Nijmegen Breakage Syndrome (NBS). Very recently, a new member of the NHEJ repair pathway, NHEJ1, was discovered, and mutations in patients with features resembling NBS were described. Here we report on five patients from four families of different ethnic origin with the NBS‐like phenotype. Sequence analysis of the NHEJ1 gene in a patient of Spanish and in a patient of Turkish origin identified homozygous, previously reported mutations, c.168C>G (p.Arg57Gly) and c.532C>T (p.Arg178Ter), respectively. Two novel, paternally inherited truncating mutations, c.495dupA (p.Asp166ArgfsTer20) and c.526C>T (p.Arg176Ter) and two novel, maternal genomic deletions of 1.9 and 6.9 kb of the NHEJ1 gene, were found in a compound heterozygous state in two siblings of German origin and in one Malaysian patient, respectively. Our findings confirm that patients with NBS‐like phenotypes may have mutations in the NHEJ1 gene including multiexon deletions, and show that considerable clinical variability could be observed even within the same family. Hum Mutat 31:1059–1068, 2010. © 2010 Wiley‐Liss, Inc.     

Ends-in vs. ends-out targeted insertion mutagenesis in <Emphasis Type="Italic">Saccharomyces castellii</Emphasis>

Gene replacement (knock-out) is a major tool for the analysis of gene function. However, the efficiency of correct targeting varies between species, and is dependent on the structure of the DNA construct. We analyzed the targeted insertion mutagenesis method in the budding yeast Saccharomyces castellii, phylogenetically positioned after the whole genome duplication event in the Saccharomyces lineage. We compared the targeting efficiency for target DNA constructs in the respective ends-in and ends-out form. For some of the constructs S. castellii showed a similar high degree of homologous recombination as S. cerevisiae. In agreement with S. cerevisiae, a higher targeting efficiency was seen for the diploid strain than for the haploid. Surprisingly, a higher degree of targeting efficiency was seen for ends-out constructs compared to ends-in constructs. This result may have been influenced by the difference in the length of the homologous target sequences used, although long homology regions of 300 bp–1 kb were used in all constructs. Remarkably, very short regions of cohesive heterologous sequences at the ends of the constructs highly stimulated random illegitimate integration, suggesting that the pathway of non-homologous end joining is highly active in S. castellii.     

Dependence of DNA double strand break repair pathways on cell cycle phase in human lymphoblastoid cells

DNA double‐strand breaks (DSBs) are usually repaired by nonhomologous end‐joining (NHEJ) or homologous recombination (HR). NHEJ is thought to be the predominant pathway operating in mammalian cells functioning in all phases of the cell cycle, while HR works in the late‐S and G2 phases. However, relative contribution, competition, and dependence on cell cycle phases are not fully understood. We previously developed a system to trace the fate of DSBs in the human genome by introducing the homing endonuclease I‐SceI site into the thymidine kinase (TK) gene of human lymphoblastoid TK6 cells. Here, we use this system to investigate the relative contribution of HR and NHEJ for repairing I‐SceI‐induced DSBs under various conditions. We used a novel transfection system, Amaxa? nucleofector, which directly introduces the I‐SceI expression vector into cell nuclei. Approximately 65% of transfected cells expressed the I‐SceI enzyme and over 50% of the cells produced a single DSB in the genome. The relative contribution of NHEJ and HR for repairing the DSB was ～100:1 and did not change with transfection efficiency. Cotransfection with KU80‐siRNA significantly diminished KU80 protein levels and decreased NHEJ activity, but did not increase HR. We also investigated HR and NHEJ in synchronized cells. The HR frequency was 2–3 times higher in late‐S/G2 phases than in G1, whereas NHEJ was unaffected. Even in late‐S/G2 phases, NHEJ remained elevated relative to HR. Therefore, NHEJ is the major pathway for repairing endonuclease‐induced DSBs in mammalian cells even in late‐S/G2 phase, and does not compete with HR. Environ. Mol. Mutagen. 2009. © 2009 Wiley‐Liss, Inc.     

Repair of plasmid DNA used for transformation of <Emphasis Type="Italic">Rhizopus oryzae</Emphasis> by gene conversion

Techniques for genetic manipulation of the filamentous fungus Rhizopus have been hampered due to a lack of understanding regarding the recombination and replication mechanisms that affect the fate of introduced DNA. The ability to target chromosomal integration of a plasmid has been difficult because DNA transformed into Rhizopus rarely integrates and is autonomously replicated in a high molecular weight concatenated arrangement (i.e., series or chain). Linearization of the plasmid prior to transformation at a site having homology with the genomic DNA yields the highest frequency of integration, but repair of the double-strand break by end-joining is still the predominant event. We recently attempted to circumvent replication of the plasmid by introducing frameshift mutations in pyrG, the R. oryzae orotidine-5-monophosphate decarboxylase gene used for selection of the vector. It was hypothesized that autonomous replication of the mutated plasmids would be incapable of restoring prototrophic growth, since the genomic pyrG also contained a mutation. However, homologous integration of the plasmid results in duplication of the pyrG gene, which can create a functional copy of pyrG if both the genomic and plasmid mutations are paired on the same duplicate copy. While this event was detected in one of the isolates, it represented less than 8% of the total transformants. The majority of transformants contained plasmid replicating autonomously in a concatenated arrangement. Sequence analysis showed that prototrophic growth was restored by repairing the non-functional pyrG sequence in the plasmid, while the genomic pyrG gene was unaltered. Frequent transfer of the genomic pyrG mutation to the plasmid suggests that gene conversion is likely occurring by recombination pathways involving break-induced replication or synthesis-dependent strand annealing.USDA: Names are necessary to report factually on available data; however, the USDA neither guarantees nor warrants the standard of the product, and the use of the name by USDA implies no approval of the product to the exclusion of others that may also be suitable.     

Evaluation of the roles of Pol zeta and NHEJ in starvation-associated spontaneous mutagenesis in the yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The vast majority of microorganisms live under starvation-associated stress conditions that cause mutagenesis despite the limitation of DNA replication and cell division. In this study, we compared the roles of polymerase zeta (Pol zeta) and non-homologous DNA-end joining (NHEJ) in starvation-associated spontaneous base substitutions and frameshifts, using yeast mutants carrying deletions of REV3 (encoding the catalytic subunit of Pol zeta), YKU80 (encoding a protein involved in the initiation of NHEJ), or both genes. We found that approximately 50% of starvation-associated spontaneous frameshifts and 40% of base substitutions required NHEJ to occur. The role of Pol zeta was only slightly less pronounced, with 30–40% of frameshifts and 35–45% of base substitutions being dependent on Rev3. In comparison with the single mutants, the rev3 yku80 double mutant showed an additive decrease in the level of both base substitutions and frameshifts, indicating that Pol zeta and NHEJ function independently in starvation-associated mutagenesis. Our results also imply that about 30% of starvation-associated base substitutions and frameshifts arise by some unknown mechanism that does not involve Pol zeta or NHEJ. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

DNA recombination in somatic plant cells: mechanisms and evolutionary consequences

In somatic cells, recombination is a means of DNA damage repair. The most severe type of damage in nuclear DNA is double-strand breaks (DSBs) which may be repaired via either non-homologous end joining (NHEJ) or homologous recombination (HR). In this review, we will summarize the basic features, the mechanisms, and the key players of both repair modes in plants with a focus on the model plant Arabidopsis thaliana. NHEJ may result in insertion of sequences from elsewhere in the genome but is much more often associated with deletions. If more than one DSB is processed simultaneously via NHEJ, besides deletions, inversions or translocations may also arise. As the germ line is only set aside late in plant development, somatic changes may be transferred to the next generation. Thus, NHEJ might influence the evolution of plant genomes and indeed seems to be an important factor of genome shrinking. Deletions may also be due to DSB-induced recombination between tandem duplicated homologous sequences by single-strand annealing (SSA). Moreover, conservative HR using the synthesis-dependent strand annealing (SDSA) mechanism operates in somatic plant cells. The efficiency of SDSA is dependent on the genomic template used as matrix for the repair of the DSB. Besides DSBs, stalled replication forks may also be processed via HR. Several DNA processing enzymes are involved in the regulation of replication initiated HR, mostly in its suppression, and we summarize the current knowledge of these processes in plants.     

Efficient Generation of Gene‐Modified Pigs Harboring Precise Orthologous Human Mutation via CRISPR/Cas9‐Induced Homology‐Directed Repair in Zygotes

Precise genetic mutation of model animals is highly valuable for functional investigation of human mutations. Clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR‐associated 9 (Cas9)‐induced homology‐directed repair (HDR) is usually used for precise genetic mutation, being limited by the relatively low efficiency compared with that of non‐homologous end joining (NHEJ). Although inhibition of NHEJ was shown to enhance HDR‐derived mutation, in this work, without inhibition of NHEJ, we first generated gene‐modified pigs harboring precise orthologous human mutation (Sox10 c.A325>T) via CRISPR/Cas9‐induced HDR in zygotes using single‐strand oligo DNA (ssODN) as template with an efficiency as high as 80%, indicating that pig zygotes exhibited high activities of HDR relative to NHEJ and were highly amendable to genetic mutation via CIRSPR/Cas9‐induced HDR. Besides, we found a higher concentration of ssODN remarkably reduced HDR‐derived mutation in pig zygotes, suggesting a possible balance for optimal HDR‐derived mutation in zygotes between the excessive accessibility to HDR templates and the activities of HDR relative to NHEJ which appeared to be negatively correlated to ssODN concentration. In addition, the HDR‐derived mutation, as well as those from NHEJ, extensively integrated into various tissues including gonad of founder pig without detected off‐targeting, suggesting CRISPR/Cas9‐induced HDR in zygotes is a reliable approach for precise genetic mutation in pigs.     

Bi‐allelic alterations in DNA repair genes underpin homologous recombination DNA repair defects in breast cancer

Homologous recombination (HR) DNA repair‐deficient (HRD) breast cancers have been shown to be sensitive to DNA repair targeted therapies. Burgeoning evidence suggests that sporadic breast cancers, lacking germline BRCA1/BRCA2 mutations, may also be HRD. We developed a functional ex vivo RAD51‐based test to identify HRD primary breast cancers. An integrated approach examining methylation, gene expression, and whole‐exome sequencing was employed to ascertain the aetiology of HRD. Functional HRD breast cancers displayed genomic features of lack of competent HR, including large‐scale state transitions and specific mutational signatures. Somatic and/or germline genetic alterations resulting in bi‐allelic loss‐of‐function of HR genes underpinned functional HRD in 89% of cases, and were observed in only one of the 15 HR‐proficient samples tested. These findings indicate the importance of a comprehensive genetic assessment of bi‐allelic alterations in the HR pathway to deliver a precision medicine‐based approach to select patients for therapies targeting tumour‐specific DNA repair defects. Copyright © 2017 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Transformation ofNeurospora crassa with circular and linear DNA and analysis of the fate of the transforming DNA

Summary We have conducted a detailed study of 108qa-2 ⁺ Neurospora transformants which were obtained by use of circular plasmid DNAs and various linear DNAs. Parallel genetic and molecular analyses have revealed that three classes of transformants can be identified: linked transformants, in which theqa-2 gene has integrated at the resident locus, unlinked transformants, where integration has occurred at other genomic sites, and a third class designated non-transmissible which fail to pass theqa-2 gene through a cross. The non-transmissible class comprises the majority of transformants and may identify those which harbor autonomously replicating plasmids. Evidence is presented which suggests that a 1.2 kB BamHI-Bg1IIqa-2 ⁺ DNA fragment might possess anars sequence. Transformation with linear plasmid DNAs and DNA fragments carrying theqa-2 gene resulted in a demonstrable increase in transformation frequency beyond that achieved with circular plasmid DNAs, but did not permit precise targeting to the resident locus. Southern analysis showed that linked transformants have only the normal residentqa-2 band whereas the unlinked transformants always possess the resident band plus at least one additional band. Multiple integration events appear to be common and include cases where only a portion of the transforming DNA has been integrated.     

Transformation of Neurospora crassa with the trp-1 gene and the effect of host strain upon the fate of the transforming DNA

Summary Neurospora trp-1 ⁺ transformants, obtained by transforming a trp-1 inl strain with plasmid DNA containing the wild type trp1 ⁺ gene, were characterized by genetic and Southern blot analyses. The transforming trp-1 gene integrated at or near the resident site in all of the trp-1 ⁺ transformants obtained with circular DNA or DNA cut within the trp-1 coding region. The frequency of homologous integration decreased substantially when the donor DNA was cleaved outside the trp-1 coding region. The transformants were very stable mitotically and, in general, also showed meiotic stability. Analysis of trp-1 ⁺ transformants obtained with another recipient strain, trp-1 ⁺ ga-2 aro-9 inl, showed that homologous integration of donor DNA occurred in only 20% of the transformants, whether circular or linear DNA was used. Thus, the host strain employed for transformation appears to be a major factor in determining the fate of transforming DNA. Southern blot analysis of transformants showed that integration of the transforming DNA at the homologous site occurred by double crossover or gene conversion events rather than by insertion of the entire plasmid DNA. Multiple and apparently non functional integration events were observed in some transformants.     

Increasing frequencies of site-specific mutagenesis and gene targeting in Arabidopsis by manipulating DNA repair pathways

Improved methods for engineering sequence-specific nucleases, including zinc finger nucleases (ZFNs) and TAL effector nucleases (TALENs), have made it possible to precisely modify plant genomes. However, the success of genome modification is largely dependent on the intrinsic activity of the engineered nucleases. In this study, we sought to enhance ZFN-mediated targeted mutagenesis and gene targeting (GT) in Arabidopsis by manipulating DNA repair pathways. Using a ZFN that creates a double-strand break (DSB) at the endogenous ADH1 locus, we analyzed repair outcomes in the absence of DNA repair proteins such as KU70 and LIG4 (both involved in classic nonhomologous end-joining, NHEJ) and SMC6B (involved in sister-chromatid-based homologous recombination, HR). We achieved a fivefold to 16-fold enhancement in HR-based GT in a ku70 mutant and a threefold to fourfold enhancement in GT in the lig4 mutant. Although the NHEJ mutagenesis frequency was not significantly changed in ku70 or lig4, DNA repair was shifted to microhomology-dependent alternative NHEJ. As a result, mutations in both ku70 and lig4 were predominantly large deletions, which facilitates easy screening for mutations by PCR. Interestingly, NHEJ mutagenesis and GT at the ADH1 locus were enhanced by sixfold to eightfold and threefold to fourfold, respectively, in a smc6b mutant. The increase in NHEJ-mediated mutagenesis by loss of SMC6B was further confirmed using ZFNs that target two other Arabidopsis genes, namely, TT4 and MPK8. Considering that components of DNA repair pathways are highly conserved across species, mutations in DNA repair genes likely provide a universal strategy for harnessing repair pathways to achieve desired targeted genome modifications.Customizable, sequence-specific nucleases make it possible to precisely modify the genomes of many higher organisms, including diverse plant species (Voytas 2013). There are three primary types of sequence-specific nucleases, namely, zinc finger nucleases (ZFNs) (Kim et al. 1996; Carroll 2011), TAL effector nucleases (TALENs) (Christian et al. 2010; Bogdanove and Voytas 2011), and meganucleases (Smith et al. 2006; Paques and Duchateau 2007). All three nuclease types introduce targeted DNA double-strand breaks (DSBs), which activate the cell''s DNA repair pathways, principally nonhomologous end-joining (NHEJ) and homologous recombination (HR) (Kanaar et al. 1998; Puchta 2005; Hartlerode and Scully 2009). NHEJ predominates in nonreplicating cells and repair is often imprecise, such that mutations are introduced at the cut site. HR, which enables gene replacement or gene targeting (GT), predominates in replicating cells. Because genome modifications made with customizable nucleases rely on DSB repair, it should be possible to manipulate DNA repair pathways to influence the type and frequency of targeted modifications attained. For example, promoting NHEJ should enhance nuclease-mediated site-specific mutagenesis; however, there are no reports of this approach being successful in plants. Strategies to enhance HR have been reported in a few plant studies; for example, high-frequency HR was obtained by overexpressing the yeast RAD54 gene (Shaked et al. 2005). Enhanced HR was also attained in Arabidopsis by knocking out RAD50 (Gherbi et al. 2001) or CAF1(Endo et al. 2006) or by overexpressing SMC6B (also known as MIM) (Hanin et al. 2000). Almost all of these studies used a GUS transgene reporter that measures intrachromosomal, single-strand annealing (SSA) and/or synthesis-dependent strand annealing (SDSA) in which sister chromatids or homologous chromosomes are used as repair templates (Orel et al. 2003; Puchta 2005). For GT, exogenous donors or chromosomally integrated, nonallelic donors are usually used. The repair mechanisms used in GT, therefore, could be quite different, and it remains to be determined whether previously demonstrated manipulations of DNA repair pathways will apply to GT of endogenous genes. One of the few attempts to influence GT in plants involved overexpression of the bacterial RecA protein, which enhanced the fidelity of DSB-induced GT in tobacco but not the overall GT frequency (Reiss et al. 2000).In this study, we tested the consequence of manipulating key regulators of NHEJ and HR on targeted mutagenesis or GT mediated by sequence-specific nucleases. In classic NHEJ (C-NHEJ), KU70 dimerizes with KU80 to form KU protein complexes, which directly bind to DSBs to initiate repair (Pastwa and Blasiak 2003). In HR, SMC6 acts when sister chromatids are used as repair templates in both human (De Piccoli et al. 2006; Potts et al. 2006) and Arabidopsis cells (Watanabe et al. 2009). SMC6 dimerizes with SMC5 to form SMC6/5 complexes that initiate repair of DSBs using sister chromatids as templates (Potts 2009). The upstream positions of KU70 and SMC6 in the NHEJ or HR pathways, respectively, made them good candidates as regulators of DNA repair pathway choice. We also chose LIG4, because it carries out a well-known and conserved function downstream from KU (Pastwa and Blasiak 2003). A ZFN that targets the endogenous Arabidopsis ADH1 gene was used to create DSBs (Zhang et al. 2010), and NHEJ mutagenesis and GT were measured in whole seedlings and rosette leaf protoplasts in each of the three DNA repair mutant backgrounds. Our results clearly demonstrate that manipulating these key DNA repair genes in Arabidopsis can influence the efficiencies and outcomes of targeted mutagenesis and GT.     

Prevalence of BRCA1/2 large genomic rearrangements in Chinese women with sporadic triple‐negative or familial breast cancer

The prevalence of BRCA1/2 large genomic rearrangements (LGRs) and their underlying mechanisms have not been fully evaluated in Chinese women with breast cancer. In this study, we determined the prevalence of BRCA1/2 LGRs in 834 patients with familial breast cancer (FBC) and 660 patients with sporadic triple‐negative breast cancer (TNBC) who were negative for BRCA1/2 small‐range mutations using the multiplex ligation‐dependent probe amplification method. We found that 20 index patients (2.4%) in the FBC group carried a BRCA1 or BRCA2 LGR, and the frequencies of BRCA1 and BRCA2 LGRs were 1.6% and 0.8%, respectively. Seven index patients (1.1%) carried a BRCA1 LGR in 660 sporadic TNBC patients, whereas no BRCA2 LGRs were found in these patients. Among the BRCA1/2 LGRs, 48.1% (13/27) were novel, and the breakpoints of the majority of the LGRs were identified. ΨBRCA1‐mediated homologous recombination (HR) and Alu‐mediated HR/non‐homologous end‐joining (NHEJ) accounted for 40% and 30% of the BRCA1 LGRs, respectively. Alu‐mediated HR accounted for 71.4% of the BRCA2 LGRs, and the remaining one‐third was generated through Long interspersed nuclear elements (LINE)‐mediated NHEJ. Our findings suggest that both FBC patients and sporadic TNBC patients should be tested for BRCA1/2 LGRs.     

A piggyBac transposon‐ and gateway‐enhanced system for efficient BAC transgenesis

Results and Conclusions: We present an enhanced system, comprising a BAC vector retrofitted with piggyBac DNA transposon elements and attL (Gateway) docking sites, that obviates these problems. Using this system, a gene‐of‐interest (such as a reporter gene) is transferred to the vector in a one‐step in vitro reaction, and piggyBac transposition mediates transgene integration at high efficiency when microinjected into mouse zygotes with piggyBac transposase mRNA. We establish proof‐of‐principle for this system using a Wilms tumour‐1 (Wt1) BAC to drive expression of an mCherry‐2A‐EGFP (RG) reporter gene, which yielded transgenic mice at a frequency of 33%, and recapitulated endogenous WT1 expression in developing gonads, kidneys and heart. The system we describe is applicable to any BAC transgenesis strategy. Developmental Dynamics 243:1086–1094, 2014. © 2014 Wiley Periodicals, Inc.     

Cloning and sequence analysis of the glucoamylase gene of Neurospora crassa

A 1.0-kb DNA fragment, corresponding to an internal region of the Neurospora crassa glucoamylase gene, gla-1, was generated from genomic DNA by the polymerase chain reaction, using oligonucleotide primers which had been deduced from the known N-terminal amino-acid sequence or from consensus regions within the aligned amino-acid sequences of other fungal glucoamylases. The fragment was used to screen an N. crassa genomic DNA library. One clone contained the gene together with flanking regions and its sequence was determined. The gene was found to code for a preproprotein of 626 amino acids, 35 of which constitute a signal and propeptide region. The protein and the gene are compared with corresponding sequences in other fungi.     

Length heterogeneity in ITS 2 and the methylation status of CCGG and GCGC sites in the rRNA genes of the genus Peronosclerospora

Summary The polymerase chain reaction (PCR) was used with primers complementary to conserved flanking sequences to amplify the internal transcribed spacer 2 (ITS 2) of the rDNA repeat units of five Peronoscleropora isolates, one each of P. sorghi, P. maydis, P. sacchari and tow of P. zeae. In contrast to the situation found in mostfungi that have been examined, length heterogeneity was evident in each sample. The rDNA composition of the amplified bands was confirmed by Southern hybridizations using an ITS 2 amplified from P. sorghi and cloned rDNA from Neurospora crassa as probes. Length heterogeneity was also detected in genomic DNA digests using the same probes. In addition to one dominant fragment for each isolate, there were several less frequent fragments of different sizes, and the isolate(s) for each species had a unique banding pattern for ITS 2. The absence of 5-methylcytosine residues in CCGG and GCGC sequences in the ribosomal genes of these four Peronosclerospora species was demonstrated by the production of identical banding patterns with ribosomal DNA probes following digestion of genomic DNA with MspI and HpaII, and by complete digestion with CfoI.     

Transformation of the mycoparasite Gliocladium

Summary Gliocladium roseum and G. virens are saprophytic fungi with biological control activity against various plant pathogens, including those causing seedling diseases in cotton. Genetic transformation systems were developed to provide the potential for incorporating additional traits to improve the biocontrol efficacy of Gliocladium. Gliocladium roseum protoplasts were transformed with G. virens genomic DNA. The 6.7 kb plasmid pH1S containing a bacterial hygromycin B resistance gene, hygB, was used to transform G. virens. Up to ten methionine-independent G. roseum transformants were recovered per microgram of G. virens DNA. Transformation frequencies as high as 150 hygromycin B-resistant transformants per microgram of circular palsmid DNA were observed with electroporation at a field strength of 500 V/cm. Total DNA was isolated from G. virens transformants and hybridized to purified hygB or pBR322 (the vector used in the pH1S construct) DNA. The hygB DNA was integrated into genomic DNA. Precise excision of the plasmid by two different restriction endonucleases provided evidence for the presence of multiple tandem copies in some transformants. The presence of multiple bands in digests of other transformants suggested multiple sites of integration.     

A region of heterogeneity adjacent to the 5s ribosomal RNA gene of cereal rusts

Summary Total genomic DNA was isolated from three cereal stem rusts, Puccinia graminis f. sp. tritici, f. sp. secalis, f. sp. avenae, and two cereal leaf rusts, P. recondita f. sp. tritici and P. coronata f. sp. avenae, and analyzed for the presence of heterogeneity in the intergenic region of the ribosomal DNA repeat unit. A 1 kb region of the repeat unit between the 26s and the 5s rRNA genes (IGR-1) was amplified by PCR and was found to be heterogeneous within each isolate and variable in size between races and species. The PCR results were confirmed by Southern blot analysis of native DNA. In an isolate of race C36(48), heterogeneity appeared to be due to variable numbers of 0.1 kb subrepeats in IGR-1. Nine wheat stem rust strains representing nine different races produced a unique pattern of heterogeneity while two different isolates of one race were identical, as were five of another. This may provide a rapid method for race identification in wheat stem rust. Heterogeneity and polymorphism in rye stem rust, oat stem rust, wheat leaf rust, and oat crown rust, was less pronounced than in wheat stem rust. In the course of this work, the 5s rRNA gene was located and its position and orientation within the ribosomal repeat unit was established.     

Construction by one-step gene replacement of Trichoderma reesei strains that produce the glucoamylase P of Hormoconis resinae

Two one-step gene replacement vectors containing either the Hormoconis resinae glucoamylase P (gamP) genomic gene or the corresponding cDNA, each under the control of the promoter of the Trichoderma reesei cellobiohydrolase 1 gene (cbh1), were constructed and use to replace the cbh1 gene in a T. reesei strain. In both vectors the cbh1 promoter is precisely fused to the gamP protein coding region. Both the gamP cDNA and the genomic gene direct the secretion of the active glucoamylase P (GAMP) enzyme from T. reesei, which indicates that the intron sequences in the genomic gamP gene are processed in T. reesei. According to the results, a T. reesei transformant strain, in which the cbh1 gene has been replaced by a single copy of the gamP genomic gene, secretes more active GAMP than does a transformant strain having three copies of the cDNA clone in tandem orientation at the cbh1 locus.     

Development of<Emphasis Type="Italic"> NF2</Emphasis> gene specific,strictly sequence defined diagnostic microarray for deletion detection

Neurofibromatosis type 2 (NF2) is an autosomal dominant cancer syndrome caused by the biallelic inactivation of the neurofibromin 2 tumor suppressor gene (NF2). Current molecular diagnostic methods for NF2 involve the detection of point mutations and/or microdeletions across the 100-kb locus from 22q12. Despite the fact that NF2 gene inactivating deletions occur in 25–30% of NF2 patients, the available approaches for high-resolution and high-throughput detection of deletions are underdeveloped. This need for improved methodology for gene copy number analysis is especially apparent when compared to a variety of methods available for accurate detection of point mutations. The microarray-based form of comparative genomic hybridization has been previously applied in the high-resolution analysis of gene copy number variation across large genomic regions. In this study we apply a PCR-based, strictly sequence-defined, repeat-free approach for the preparation of a diagnostic microarray for the detection of disease-causing deletions in the NF2 gene. The methodology is based on the preselection of target DNA by excluding redundant sequence within the NF2 locus using bioinformatics. This approach allows a significant increase in the resolution of deletion detection. The current average resolution of analysis across the NF2 locus is 23 kb. Therefore this NF2 gene-specific microarray is the first high-resolution tool for detection of diagnostically significant gene copy number aberrations. This microarray should now be applied in the analysis of an extensive series of NF2 patients, and hence we would like to call for such samples.Supplementary material is available at . On that page (frame on the left side) a link takes you directly to the supplementary materialAbbreviations ANILFR Average normalized interlocus fluorescence ratio - Array-CGH Microarray-based comparative genomic hybridization - CGH Comparative genomic hybridization - NF2 Neurofibromatosis type 2K.K. Mantripragada and P.G. Buckley contributed equally to this work.