测定橡树岭ras-1 bd菌株突变的莫里斯维尔菌株

Kaitlyn Beasley, T. Lamb, W. Versaw, Deborah Bell-Pedersen
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Versaw and Deborah Bell-Pedersen* *Center for Biological Clocks Research and Department of Biology, Texas A&M University, College Station, TX 77843 Fungal Genetics Newsletter 53:30-33 We describe the construction of a Neurospora crassa Mauriceville strain carrying the ras-1 mutation marked by the bacterial bd hygromycin resistance gene, hph (new FGSC # 10156). This strain is valuable for mapping mutations in Oak Ridge strains that carry the bd mutation. The bd mutation has been a benefit to circadian rhythm research as it slows down wild type growth rates and sharpens the conidial banding pattern on racetubes (Sargent et al., 1966; Bell-Pedersen et al., 2005). Recent work (Belden et al., 2006) has shown that the bd mutation lies in the ras-1 gene. Mutations that affect circadian banding patterns are typically isolated in strains carrying the ras-1 allele. Mapping such mutations by the CAPS method (Jin et al., in press) requires that the mutant phenotype be followed in bd a cross to a wild type Mauriceville strain. Assuming non-linkage, only half of the progeny will be bd, and thus readily scorable. Insertion of the ras-1 allele into the Mauriceville parent renders all progeny useful for segregation analysis. Furthermore, bd marking ras-1 with the hygromycin resistance gene, hph, permits a simple drug resistance test to determine linkage to ras-1. bd The strategy for gene replacement was similar to published split marker gene deletion strategies (Catlett et al., 2003; Colot et al., 2006). However, rather than deleting the wild type gene, we replaced it with the bd allele and inserted the hph gene in the 3'UTR at position + 225 from the stop codon (Figure 1). Figure 1. Schematic diagram of ras-1 genetic manipulations. Regions of homology are indicated by vertical hatch marks; there are 763 bp of homology between the split hph fragments, 3223 bp of homology at the 5' end, and 2582 bp of homology at the 3' end. Pvu II and Xho I sites are marked to show the differences between the wild type (wt) genomic (g) locus and the proper ras1 -hph integrant. The dashed line indicates a gap where the hph gene is integrated and the dotted lines indicate flanking genomic bd DNA that remains unchanged. The replacement fragments were generated in two steps. The first step involved amplification of ras-1 genomic regions from the bd Oak Ridge bd strain (FGSC 1858). The 5' region was amplified using primers ras1 F1 and ras1-hyg R1, while the 3' region was amplified using primers hyg-ras1 F2 and ras1 R2. The second step was to generate hybrid pieces that contained a portion of the bacterial hph gene fused to either 5' or 3' regions of ras-1 (Figure 1). The 5' split marker fragment was generated by amplification bd of the 5' region of ras-1 and the complete hph gene, with primers ras1 F1 and YG2. The 3' split marker fragment was generated bd by amplification of the 3' region of ras-1 and the complete hph gene, with primers HY2 and ras1 R2. The complete hph gene bd was obtained by amplification of pBP15 (a gift from D. Ebbole) with primers M13F2 and M13R2. 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Furthermore, bd marking ras-1 with the hygromycin resistance gene, hph, permits a simple drug resistance test to determine linkage to ras-1. bd The strategy for gene replacement was similar to published split marker gene deletion strategies (Catlett et al., 2003; Colot et al., 2006). However, rather than deleting the wild type gene, we replaced it with the bd allele and inserted the hph gene in the 3'UTR at position + 225 from the stop codon (Figure 1). Figure 1. Schematic diagram of ras-1 genetic manipulations. Regions of homology are indicated by vertical hatch marks; there are 763 bp of homology between the split hph fragments, 3223 bp of homology at the 5' end, and 2582 bp of homology at the 3' end. Pvu II and Xho I sites are marked to show the differences between the wild type (wt) genomic (g) locus and the proper ras1 -hph integrant. The dashed line indicates a gap where the hph gene is integrated and the dotted lines indicate flanking genomic bd DNA that remains unchanged. 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引用次数: 1

摘要

我们描述了一株携带细菌耐潮霉素基因hph(新fgsc# 10156)标记的ras-1bd突变的粗糙神经孢子虫Mauriceville菌株的构建。该菌株对绘制携带bd突变的橡树岭菌株的突变图谱很有价值。本作品采用知识共享署名-相同方式共享4.0许可协议。这篇常规论文发表在《真菌遗传学报告》上:http://newprairiepress.org/fgr/vol53/iss1/9 30真菌遗传学通讯A. Kaitlyn Beasley*, Teresa M. Lamb*, Wayne K. Versaw, Deborah Bell-Pedersen* *德州农工大学生物时钟研究中心,大学城我们描述了一株携带细菌耐水霉素基因hph(新fgsc# 10156)标记的ras-1突变的草神经孢子虫Mauriceville菌株的构建。该菌株对绘制携带bd突变的橡树岭菌株的突变图谱很有价值。bd突变对昼夜节律研究是有益的,因为它减缓了野生型的生长速度,并使总状管上的分生孢子带型变尖(Sargent et al., 1966;Bell-Pedersen et al., 2005)。最近的研究(Belden et al., 2006)表明,bd突变存在于ras-1基因中。影响昼夜带带模式的突变通常在携带ras-1等位基因的菌株中分离出来。用CAPS方法绘制这种突变图谱(Jin et al., in press)需要在与野生型Mauriceville菌株杂交时遵循突变表型。假设非连锁,只有一半的后代将是bd,因此很容易得分。将ras-1等位基因插入到毛里斯维尔亲本中,使所有后代对分离分析都有用。此外,bd用潮霉素耐药基因hph标记ras-1,允许进行简单的耐药试验以确定与ras-1的连锁关系。bd基因替换策略类似于已发表的分裂标记基因删除策略(Catlett et al., 2003;Colot et al., 2006)。然而,我们没有删除野生型基因,而是用bd等位基因替换它,并在停止密码子+ 225位置的3'UTR中插入hph基因(图1)。ras-1基因操作示意图。同源区域用垂直的舱口标记表示;HPH片段的同源性为763 bp,其中5′端同源性为3223 bp, 3′端同源性为2582 bp。Pvu II和Xho I位点被标记,以显示野生型(wt)基因组(g)位点与适当的ras1 -hph整合子之间的差异。虚线表示hph基因整合的间隙,虚线表示两侧基因组bd DNA保持不变。替换片段分两步生成。第一步是扩增橡树岭bd菌株(FGSC 1858)的ras-1基因组区域。用引物ras1 F1和ras1-hyg R1扩增5′区,用引物hyg-ras1 F2和ras1 R2扩增3′区。第二步是产生含有一部分细菌hph基因融合到ras-1的5'或3'区域的杂交片段(图1)。5'分裂标记片段是通过扩增ras-1的5'区域和完整的hph基因产生的,引物为ras1 F1和YG2。用引物HY2和ras1 R2扩增ras-1的3′区和完整的hph基因,得到3′分裂标记片段bd。用引物M13F2和M13R2扩增pBP15 (D. Ebbole赠送),获得完整的hph基因bd。pBP15质粒含有来自pCB1003 (Carroll et al., 1994)亚克隆到pBluescript II SK的EcoRV位点的1.4kb HpaI PtrpC-hph片段(New Prairie Press, 2017)
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A ras-1 bd Mauriceville strain for mapping mutations in Oak Ridge ras-1 bd strains
We describe the construction of a Neurospora crassa Mauriceville strain carrying the ras-1bd mutation marked by the bacterial hygromycin resistance gene, hph (new FGSC # 10156). This strain is valuable for mapping mutations in Oak Ridge strains that carry the bd mutation. Creative Commons License This work is licensed under a Creative Commons Attribution-Share Alike 4.0 License. This regular paper is available in Fungal Genetics Reports: http://newprairiepress.org/fgr/vol53/iss1/9 30 Fungal Genetics Newsletter A ras-1 Mauriceville strain for mapping mutations in Oak Ridge ras-1 strains bd bd A. Kaitlyn Beasley*, Teresa M. Lamb*, Wayne K. Versaw and Deborah Bell-Pedersen* *Center for Biological Clocks Research and Department of Biology, Texas A&M University, College Station, TX 77843 Fungal Genetics Newsletter 53:30-33 We describe the construction of a Neurospora crassa Mauriceville strain carrying the ras-1 mutation marked by the bacterial bd hygromycin resistance gene, hph (new FGSC # 10156). This strain is valuable for mapping mutations in Oak Ridge strains that carry the bd mutation. The bd mutation has been a benefit to circadian rhythm research as it slows down wild type growth rates and sharpens the conidial banding pattern on racetubes (Sargent et al., 1966; Bell-Pedersen et al., 2005). Recent work (Belden et al., 2006) has shown that the bd mutation lies in the ras-1 gene. Mutations that affect circadian banding patterns are typically isolated in strains carrying the ras-1 allele. Mapping such mutations by the CAPS method (Jin et al., in press) requires that the mutant phenotype be followed in bd a cross to a wild type Mauriceville strain. Assuming non-linkage, only half of the progeny will be bd, and thus readily scorable. Insertion of the ras-1 allele into the Mauriceville parent renders all progeny useful for segregation analysis. Furthermore, bd marking ras-1 with the hygromycin resistance gene, hph, permits a simple drug resistance test to determine linkage to ras-1. bd The strategy for gene replacement was similar to published split marker gene deletion strategies (Catlett et al., 2003; Colot et al., 2006). However, rather than deleting the wild type gene, we replaced it with the bd allele and inserted the hph gene in the 3'UTR at position + 225 from the stop codon (Figure 1). Figure 1. Schematic diagram of ras-1 genetic manipulations. Regions of homology are indicated by vertical hatch marks; there are 763 bp of homology between the split hph fragments, 3223 bp of homology at the 5' end, and 2582 bp of homology at the 3' end. Pvu II and Xho I sites are marked to show the differences between the wild type (wt) genomic (g) locus and the proper ras1 -hph integrant. The dashed line indicates a gap where the hph gene is integrated and the dotted lines indicate flanking genomic bd DNA that remains unchanged. The replacement fragments were generated in two steps. The first step involved amplification of ras-1 genomic regions from the bd Oak Ridge bd strain (FGSC 1858). The 5' region was amplified using primers ras1 F1 and ras1-hyg R1, while the 3' region was amplified using primers hyg-ras1 F2 and ras1 R2. The second step was to generate hybrid pieces that contained a portion of the bacterial hph gene fused to either 5' or 3' regions of ras-1 (Figure 1). The 5' split marker fragment was generated by amplification bd of the 5' region of ras-1 and the complete hph gene, with primers ras1 F1 and YG2. The 3' split marker fragment was generated bd by amplification of the 3' region of ras-1 and the complete hph gene, with primers HY2 and ras1 R2. The complete hph gene bd was obtained by amplification of pBP15 (a gift from D. Ebbole) with primers M13F2 and M13R2. The pBP15 plasmid contains a 1.4kb HpaI PtrpC-hph fragment from pCB1003 (Carroll et al., 1994) subcloned into the EcoRV site of pBluescript II SK Published by New Prairie Press, 2017
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