几种鱼肝线粒体基因组的研究

我们用简易方法提纯了武昌鱼、乌鱼、草鱼和白鲢肝脏线粒体(mt)DNA。武昌鱼mt DNA经五种限制酶BamHI、BglⅡ、BglI、EcoRI和HindⅢ单酶完全酶解分别产生2、2、3、3和3个片段。乌鱼肝mt DNA用EcoRI、BamHI、pstI和BglⅡ单酶解分别得到1、2、2和2个片段。草鱼mt DNA亦作相应的酶解。所有各片段经琼脂糖凝胶电泳测定出它们的分子量(MW):武昌鱼肝mt DNA的MW10.2×10~6道尔顿,长约16.6kb;乌鱼肝mt DNA MW9.99×10~6道尔顿,长16.2kb;草鱼mt DNA的分子量10.13×10~6,长16.22×10kb。用七对限制酶双酶全酶解构建出武昌鱼mt DNA五种限制酶图谱。用六对限制酶双酶解构建出乌鱼mt DNA四种限制酶图。以酵母线粒体15S rRNA为探针对武昌鱼、白鲢鱼和乌鱼mt DNA12S rRNA基因进行了初步定位。     

Structure of Mitochondrial Dna From Paramecium Tetraurelia*

Mitochondrial DNA (mtDNA) from endosymbiote-free stocks of Paramecium tetraurelia was isolated by 2 procedures. the buoyant density of the mtDNA in neutral CsCI was 1.702 gm/cm³. a value consistent with the melting temperature of the mtDNA. Only linear molecules were observed by electron microscopy. These molecules were homogeneous in size with a monomer molecular weight of 25.6 × 10⁶ daltons. the size of the mtDNA determined after digestion with the restriction endonucleases EcoRI or Hind III agreed with the value obtained by electron microscopy. These studies also revealed that the digestion pattern of mtDNA from stock 172 differed from that of the other 3 stocks (51, 127. 203) examined. Some mtDNA molecules exhibited snapback reassociation following denaturation.     

Ovine mitochondrial DNA: restriction enzyme analysis, mapping and sequencing data

Restriction endonuclease fragment patterns of mitochondrial DNA (mtDNA) in sheep were analysed with 11 enzymes. Four breeds (Merinolandschaf, Rhoenschaf, Schwarzkoepfiges Fleischschaf and Skudde) of domestic sheep and European Mouflon were examined. A restriction map with 28 cleavage sites of seven enzymes was established. KpnI and PstI do not cut ovine mtDNA. Two EcoRI fragments of Merinolandschaf, Rhoenschaf and Mouflon each were cloned and partially sequenced. Intraspecific nucleotide sequence differences within 1.101 kb ranged from 0.09 to 0.27%. Hybridization analysis with a fragment of porcine mtDNA along with sequencing data from cloned fragments was used for orientation of the restriction map along the bovine sequence. Ovine mtDNA sequences encompassing parts of the Cyt.b-, ND5-, CoIII- and ATPase6 genes were compared with the corresponding sequences of the bovine mtDNA.     

A T4 DNA fragment containing genes for the baseplate central plug: Endonuclease restriction, gene expression and cell wall changes

Summary A fragment of Escherichia coli bacteriophage T4D DNA, containing 6.1 Kbp which included the six genes (genes 25, 26, 51, 27, 28 and 29) coding for the tail baseplate central plug has been partially characterized. This DNA fragment was obtained originally by Wilson et al. (1977) by the action of the restriction enzyme EcoRI on a modified form of T4 DNA and was inserted in the pBR322 plasmid and then incorporated into an E. coli K12 strain called RRI. This plasmid containing the phage DNA fragment has now been reisolated and screened for cleavage sites for various restriction endonucleases. Restriction enzymes Bgl 11 and Xbal each attacked one restriction site and the enzyme Hpa 1 attacked two restriction sites on this fragment. The combined digestion of the hybrid plasmid containing the T4 EcoRI DNA fragment conjugated to the pBR322 plasmid with one of these enzymes plus Bam H1 restriction enzyme resulted in the localization of the restriction site for Bgl 11, Xba 1 and Hpa 1. Escherichia coli strain B cells were transformed with this hybrid plasmid and found to have some unexpected properties. E. coli B cells, which are normally restrictive for T4 amber mutants and for T4 temperature sensitive mutants (at 44°) after transformation, were permissive for 25am, 26am and 26^Ts, 51am, and 51^Ts, 27^Ts, and 28^Ts T4 mutants. Extracts from the transformed E. coli cells were found in complementation experiments to contain the gene 29 product, as well as the gene 26 product, the gene 51 product, and the gene 27 product. The complementation experiments and the permissiveness of the transformed E. coli B cells to the various conditional lethal mutants clearly showed that the six T4 genes were producing all six gene products in these transformed cells. However, these cells were not permissive for T4 amber mutants in genes 27, 28, and 29. The transformed E. coli B cells, as compared to untransformed cells, were found to have altered outer cell walls which made them highly labile to osmotic shock and to an increased rate of killing by wild type T4 and all T4 amber mutants except for T4 am29. The change in cell walls of the transformed cells has been found to be due to the T4 baseplate genes on the hybrid plasmid, since E. coli B transformed by the pBR322 plasmid alone does not show the increase in osmotic sensitivity.     

Analysis of mitochondrial DNA species in interspecific hybrid somatic cells using restriction endonucleases. Identification of recombinant mtDNA molecules

Interspecific hybrid cells were isolated by fusion between thymidine kinase-deficient (TK⁻) mouse B82 cells and hypoxanthine-guanine-phosphoribosyl-transferase-deficient (HGPRT⁻) rat L6TG cells, and cultivating them in selective medium with hypoxanthine-aminopterin-thymidine (HAT). Karyo-type analysis revealed that they contained both mouse and rat chromosomes. Mitochondrial DNA (mtDNA) species of the hybrid cells were identified by digesting them with three kinds of restriction endonucleases, Hae II, EcoR I and Hpa II. Their restriction endonuclease cleavage patterns indicated that a portion of the mtDNAs was of mouse parent cell origin, while the remainings were recombinant molecules, i.e., part of the rat mtDNA sequence could be detected, but not whole rat mtDNA. The molecular weights of hybrid cell mtDNAs were calculated to be almost the same as that of the parent cells (˜10⁷ D).     

A partial map of the circular mitochondrial genome of Drosophila melanogaster. Location of EcoRI-sensitive sites and the adenine-thymine- rich region

The mitochondrial genome of Drosophila melanogaster is a circular DNA molecule of mol wt 12.35 X 10(6) daltons. A single region accounting for approx. 25% of this molecule can be reproducibly differentially denatured presumably because it is rich in adenine and thymine. We have mapped on the circular mitochondrial genome of D. melanogaster the relative positions of this adenine-thymine (A-T) rich region and the sites sensitive to cleavage by the restriction endonuclease EcoRI, using agarose gel electrophoresis and electron microscopy. Digestion of mitochondrial DNA (mtDNA) molecules to completion with EcoRI resulted in the production of four fragments, A, B, C, and D which represent (+/- SD) 58.9 +/- 1.1%, 27.5 +/- 0.8%, 8.9 +/- 0.5%, and 4.5 +/- 0.3%, of the circular genome length, respectively. Fragments produced by EcoRI digestion and circularized by incubation at 2 degrees C also fell into four distinct length groups with means (+/- SD) of 59.1 +/- 0.5%, 27.5 +/- 0.5%, 9.2 +/- 0.3%, and 4.6 +/- 0.2% of the circular genome length. From a consideration of the lengths of fragments resulting from incomplete EcoRI digestion, it was determined that the arrangement of the fragments in the circular genome was A-C-B-D. By electron microscope examination of partially denatured EcoRI fragments, the A-T- rich region was shown to be located in the A fragment closer to one end than to the other. By similar partial-denaturation studies of fragments resulting from incomplete EcoRI digestion, it was determined that, in the circular genome, of the two EcoRI sites which define the limits of the A fragment, the site between the A and D fragment lies nearest to the A-T-rich region.     

Transformation of hamster embryo fibroblasts by a specific fragment of the herpes simplex virus genome

Isolated restriction endonuclease fragments of the herpes simplex virus type 1 (HSV-1) genome were introduced into hamster embryo cells to identify DNA sequences capable of transforming the cells with respect to acquisition of properties correlated with tumorigenicity. One of the fragments generated by cleavage of HSV-1 DNA with the restriction endonuclease Xba I was found to induce transformation at a frequency of about 10 colonies per quantity of fragment recovered from 1 μg of uncut DNA; fractions containing the other Xba I fragments failed to induce transformation reproducibly, although occasional colonies were detected. The fragment with transforming activity (Xba I-F) is 15.5 × 10⁶ daltons in molecular weight and is located between 0.30 and 0.45 map units on the HSV-1 genome. The Xba I-F transformants obtained were selected for their ability to replicate in low concentrations of serum; in addition, they were found to attain high saturation densities in the presence of 10% serum and to form colonies in semisolid medium. Moreover, the transformed cells produced at least one of the viral gene products (a membrane glycoprotein) encoded in the fragment used for transformation, indicating not only that viral DNA was incorporated into the cells, but also that viral genes were expressed.     

DNA of Epstein-Barr virus. IV. Linkage map of restriction enzyme fragments of the B95-8 and W91 strains of Epstein-Barr Virus.

The arrangement of EcoRI, Hsu I, and Sal I restriction enzyme sites in the DNA of the B95-8 and W91 isolates of Epstein-Barr virus (EBV) has been determined from the size of the single-enzyme-cleaved fragments and from blot hybridizations that identify which fragments cut from the DNA with one enzyme contain nucleotide sequences in common with fragments cut from the DNA with a second enzyme. The DNA of the B95-8 isolate was the prototype for this study. The data indicate that (i) approximately 95 X 10(6) to 100 X 10(6) daltons of EBV (B95-8) DNA is in a consistent and unique sequence arrangement. (ii) Both termini are variable in length. One end of the molecule after Hsu I endonuclease cleavage consists of approximately 3,000 base pairs, with as many as 10 additional 500-base pair segments. The opposite end of the molecule after Sal I endonuclease cleavage consists of approximately 1,500 base pairs, with as many as 10 additional 500-base pair segments. (iii) The opposite ends of the molecule contain homologous sequences. The high degree of homology between the opposite ends of the molecule and the similarity in size of the "additional" 500-base pair segments suggests that there are identical repeating units at both ends of the DNA. The arrangement of restriction endonuclease fragments of the DNA of the W91 isolate of EBV is similar to that of the B95-8 isolate and differs from the latter in the presence of approximately 7 X 10(6) daltons of "extra" DNA at a single site. Thus, the size of almost all EcoRI, Hsu I, and Sal I fragments of EBV (W91) DNA is identical to that of fragments of EBV (B95-8) DNA. A single EcoRI fragment, C, of EBV (W91) DNA is approximately 7 X 10(6) daltons larger than the corresponding EcoRI fragment of EBV (B95-8) DNA. Digestion of EBV (W91) DNA with Hsu I or Sal I restriction endonucleases produces two fragments (Hsu I D1 and D2 or Sal I G2 and G3) which differ in total size by approximately 7 X 10(6) daltons from the fragments of EBV (B95-8) DNA. Furthermore, the EcoRI, Hsu I, and Sal I fragments of EBV (W91) and (B95-8) DNAs, which are of similar molecular weight, have homologous nucleotide sequences. Moreover, the W91 fragments contain only sequences from a single region of the B95-8 genome. Two lines of evidence indicate that the "extra" sequences present in W91 EcoRI fragment C are viral DNA and not cellular. (i) The molecular weight of the "enlarged" EcoRI C fragment of EBV (W91) DNA is identical to that of the EcoRI C fragment of another isolate of EBV (Jijoye), (ii) The HR-1 clone of Jijoye has previously been shown to contain DNA which is not present in the B95-8 strain but is present in the EcoRI C and Hsu I D2 and D1 fragments of EBV (W91) DNA (N. Raab-Traub, R. Pritchett, and E. Kieff, J. Virol. 27:388-398, 1978).     

An estimate of the physical distance between two linked markers inHaemophilus influenzae

Using DNA clones, the physical distance between the linked genesnov andstr inHaemophilus influenzae was estimated. Although none of the cloned inserts contained both the markers, pJ1-8Str^R 13 (insert of 18·7 kb) includedstr gene at one end and part ofnov gene at the other end of the insert. By EcoRI restriction analysis and by Southern hybridization, the distance between the two EcoRI sites, cutting at which inactivates the two genes, was estimated to be 17·7 kb. A single continuous EcoRI fragment (containing 4EcoRI sites within it) carrying both the genes intact would need to be 20·4 kb in size. These estimates were confirmed independently using different clones ofnov ^r andstr ^r alleles as probes for hybridization with BamHI-digested chromosomal DNA.     

Genome analysis ofPropionibacterium freudenreichii by pulsed-field gel electrophoresis

Preparations of intact genomic DNA from 23 strains ofPropionibacterium freudenreichii were compared by digestion with restriction endonucleases and subsequent transverse alternating field electrophoresis (TAFE). Seven restriction enzymes,AsnI,DraI,HpaI,SnaBI,SpeI,SspI, andXbaI, produced DNA fragments useful for strain comparisons. A characteristic restriction fragment pattern was identified for 18 of the 23 strains. Estimates for the genome size of theP. freudenreichii strains ranged from 1.6×10⁶ to 2.3×10⁶ base pairs based on the sum of fragment sizes obtained with restriction digests. Restriction endonuclease patterns resolved by TAFE are useful for strain identification.     

Fractionation and molecular weight determination of deoxyribonucleic acid fragments using agarose column chromatography

DNA fragments of several sizes have been produced by shearing E. coli DNA under different pressures. These fragments have been used to demonstrate that column chromatography on agarose Bio-Gel A-15M can provide a rapid, inexpensive fractionation and sizing method for single-stranded nucleic acids having masses between 10⁵ and 10⁶ daltons. Both chromatographic and electrophoretic analysis of the sheared DNA indicated that discrete fragment populations were produced at each shearing pressure and that these fragments were distributed essentially symmetrically around a mean piece size. The average molecular weight of the several DNA fragment distributions was determined electrophoretically by comparison with standard DNA fragments obtained from restriction endonuclease cleavage of SV40 viral DNA. The molecular weights of the denatured, sheared fragments (single-stranded) ranged from 1.25 × 10⁵ to 7.4 × 10⁵. The single-stranded DNA fragments were chromatographed over agarose Bio-Gel A-15M and a linear relationship was found to exist between the mobilities and logarithms of the molecular weights. Readily available tRNA, 5s RNA, and φX174 single-stranded circular DNA chromatographed at the extremes of the linear relationship and could be used to calibrate the column chromatography.     

应用CRISPR/Cas13b编辑技术治疗TNNT2R141W转基因小鼠的扩张型心肌病

本研究旨在应用CRISPR/Cas13b系统对TNNT2R141W转基因扩张型心肌病（dilated cardiomyopathy,DCM）小鼠（DCM小鼠）进行探索性治疗,尝试发现治疗扩张型心肌病的一种新方式,为CRISPR/Cas13b系统在体内应用提供实验基础。随机设计11种Cas13b-TNNT2 gRNA并成功构建表达质粒,把它和人源TNNT2过表达质粒共同转染到293T细胞中,通过实时定量PCR（quantitative real-time PCR,Q-PCR）检测人源TNNT2 mRNA的表达水平。结果显示,gRNA 2引导Cas13b敲低目标基因的效率最高,达到80%（P<0.0001）。把gRNA2表达质粒包装到慢病毒载体中转导出生后1天的DCM小鼠原代心肌细胞,Q-PCR检测结果表明CRISPR/Cas13b系统对人源TNNT2 mRNA的敲低效率达到55%（P<0.01）。把PspCas13b和gRNA2的表达载体分别包装到AAV9病毒载体中,然后将200 μL 约1×1012 AAV9病毒颗粒通过尾静脉注射到4月龄DCM小鼠体内,待注射小鼠发育至5月龄时,Q-PCR检测结果显示,AAV9+DCM组TNNT2R141W表达水平较未注射组对照明显下降至40%（P<0.01）。对5月龄野生型（WT）、DCM（未注射病毒组）和AAV9+DCM（基因组编辑工具注射组）三组小鼠的心脏形态、心功能、心肌纤维化和心力衰竭等表型的观察结合显示：DCM小鼠的心脏形态异常,而AAV9+DCM小鼠心脏形态趋于正常;对三组小鼠的心脏进行超声心动图并对心功能指标进行统计发现,DCM组较WT组小鼠的左心室射血分数（left ventricular percent ejection fraction,LV EF%）、左心室短轴缩短率（left ventricular percent fractional shortening,LV FS%）分别下降了50.4%（P<0.0001）,55.1%（P<0.0001）,而AAV9+DCM组较DCM组小鼠的LV EF%、LV FS%分别上升了66.5%（P<0.01）,77.0%（P<0.01）;通过Q-PCR和天狼星红染色检测三组小鼠的心脏纤维化程度,结果显示DCM组较WT组小鼠的Col3a1和Postn两种纤维化基因,分别高表达5.2倍（P<0.001）、4.5倍（P<0.01）,而AAV9+DCM组较DCM组小鼠两种基因表达分别下降了2.0倍（P<0.05）、1.4倍（NS）,天狼星红染色结果显示纤维化区域明显下降;通过Q-PCR和蛋白质免疫印迹分别检测三组小鼠的心脏心力衰竭基因Nppb mRNA和Nppa蛋白质的表达水平,结果表明DCM组较WT组小鼠Nppb mRNA表达上升14.2倍（P<0.01）,而AAV9+DCM组较DCM组小鼠Nppb mRNA表达明显下降下降2.8倍（P<0.05）,Nppa蛋白质表达趋势与Nppb相同。把gRNA 5和含有R141W突变（gRNA 5T）和正常的TNNT2 mRNA（gRNA 5V）序列分别组合转染到293T细胞中,通过Q-PCR检测两种序列mRNA的表达水平。结果显示,gRNA 5T序列表达效率为30%（P<0.0001）,而并未检测到gRNA 5V mRNA的敲低。本研究通过设计靶向TNNT2R141W mRNA的gRNA,特异性敲低TNNT2R141W转基因小鼠体内突变的mRNA,有效改善了转基因小鼠的心功能,为临床进一步探索扩张型心肌病的治疗奠定了实验室基础。     

Endonucleolytic cleavage of murine leukemia virus 35S RNA by microsome-associated nuclease.

Moloney murine leukemia virus 35S RNA (molecular weight 3 to 3.4 × 10⁶) is cleaved by nuclease activity present in microsomal fractions from MLV infected or uninfected mouse embryo cells to two RNA species of approximate molecular weights 1.8 × 10⁶ and 1.5 × 10⁶. Microsomal fractions from MLV infected and uninfected cells also contained nucleolytic activity that solubilized [³H]poly(A)·poly(U) but not [³H]poly(C) or [³H]poly(U); the cleavage of poly(A)·poly(U) was inhibited by ethidium bromide. The cleavage of MLV RNA was also inhibited by ethidium bromide, suggesting double stranded regions in 35S RNA as the site of cleavage.     

Specific Origin in SV40 DNA Replication

THE oncogenic virus SV40 contains a covalently closed circular DNA molecule of 3 × 10⁶ molecular weight¹. In infected permissive cells, SV40 DNA replicates through a Cairns type intermediate² with the parental strands forming a partially twisted, covalently closed molecule³. We have used a specific bacterial restriction endonuclease⁴ to analyse SV40 DNA replication. The restriction endonuclease of H. influenzae makes double-strand breaks in DNA at specific hexanucleotide sequences^{5, 6} and splits SV40 DNA into eleven fragments, separable by Polyacrylamide gel electrophoresis, ranging in molecular weight from 6.5 × 10⁵ (about 20% of the molecule) to 7.4 × 10⁴ (about 2.5% of the molecule). The largest eight fragments are present in the digest in amounts equimolar with the starting DNA⁴. Therefore, by digesting labelled replicating SV40 DNA and newly completed DNA and measuring the relative yield of each fragment, we could determine whether a particular region of the DNA is synthesized first or last and also estimate the time needed to replicate one molecule completely.     

Chloroplast and Mitochondrial DNA Variation in HORDEUM VULGARE and HORDEUM SPONTANEUM

A survey of restriction fragment polymorphism in Hordeum vulgare and Hordeum spontaneum was made using 17 and 16 hexanucleotide restriction endonucleases on chloroplast (cp) and mitochondrial (mt) DNA, respectively. The plant accessions originated from various places throughout the Fertile Cresent and Mediterranean. The types of changes in cpDNA consisted of nucleotide substitutions and insertions and deletions on the order of 100 base pairs. In contrast, mtDNA has most likely undergone larger insertions and deletions of up to 20 kilobase pairs in addition to rearrangements. Grouping of mtDNA fragment data showed that in some cases geographical affinities existed between the two species, whereas in others there were no clear affinities. Nucleotide diversity estimates derived from the restriction fragment data were used in a number of comparisons of variability. Comparisons of overall mtDNA variability (nucleotide diversity = 9.68 x 10^-4) with cpDNA variability (nucleotide diversity = 6.38 x 10^-4 ) indicated that the former are somewhat more variable. Furthermore, there was no indication that the wild H. spontaneum (cpDNA diversity = 5.57 x 10^-4; mtDNA diversity = 6.04 x 10 ^-4) was more variable than the land races of H. vulgare (cpDNA diversity = 5.88 x 10^-4; mtDNA diversity = 9.79 x 10^-4). In fact, on the basis of mtDNA diversity, H. vulgare was the more variable species. Comparison of organelle nucleotide diversity estimates with an estimate of nuclear nucleotide diversity derived from existing isozyme data provided evidence that both organelle genomes are evolving at a slower rate than the nuclear genome.     

Restriction endonuclease analysis of mitochondrial DNA of three farm animal species: Cattle, sheep and goat

Five restriction endonucleases (HindIII, BgIII, EcoRI, EcoRV and BamHI) were employed to analyse mitochondrial DNA of cattle, sheep and goat. The results showed completely different restriction patterns of mtDNA among the three bovid species. A total of 11, 16, and 17 restriction fragments in cattle, sheep and goat respectively, were detected by the five restriction endonucleases. Average total sizes of mtDNA of cattle, sheep and goat were found to be 16.49 ± 0.18, 16.30 ± 0.25 and 16.44 ± 0.08 kb, respectively. The mtDNA cleavage patterns were identical for all seven individuals belonging to two cattle breeds and for 10 individuals from one sheep breed.     

Kinetic studies on the cleavage of adenovirus DNA by restriction endonuclease Eco RI.

The kinetics of cleavage of DNA from Adenovirus Type 1 (Ad1), Type 5 (Ad5) and Type 6 (Ad6) by restriction endonuclease EcoRI was investigated by quantitative evaluation of the fluorescence from ethidium stained DNA fragments separated on agarose gels. The apparent rate constants of cleavage at different cleavage sites have been determined and large differences in the cleavage rates of the individual sites within one type of DNA were found. From the kinetics of cleavage information on the sequence of the DNA fragments can be obtained. The order of the fragment A, B, C, D of Ad6 DNA obtained after complete cleavage by restriction endonuclease Eco RI was found to be A-D-C-B; the order of the corresponding fragments A, B, C of Ad1 and Ad5 DNA was found to be A-C-B.     

Simple method of cloning eukaryote DNA: production of certain new ribosomal genes of Drosophila

We propose a simple method which allows to receive a collection of clones containing recombinant plasmids. It is based on the ligation of the longer fragment of pBR332 formed by EcoRI and BamH1 with eukaryotic DNA (from Drosophila melanogaster embryo in this case) partially cleaved with EcoRI and BamHI. This approach gave us 10(4) colonies from 1 microgram of Drosophila DNA and 0.1 microgram of the BamHI--EcoRI "vector". About 0.5% of all clones carried the fragments of ribosomal genes with insertions in the 26S gene. Ribosomal genes lacking insertions did not enter the collection due to some peculiarities in their restriction map. The sites of cleavage are mapped in eight recombinant plasmide for HindIII, BamHI and EcoRI. These maps show that some insertions within 26S gene have not been cloned earlier. The mean length of cloned fragments is 11.8 kilobases, the mean number of EcoRI and BamHI restriction sites are 1.2 and 1.0, respectively. The electrophoretical screening of plasmids using cetyl trimethyl ammonium bromide was developed.