Derivation of a restriction map of bacteriophage T3 DNA and comparison with the map of bacteriophage T7 DNA.

The DNA of bacteriophage T3 was characterized by cleavage with seven restriction endonucleases. AvaI, XbaI, BglII, and HindIII each cut T3 DNA at 1 site, KpnI cleaved it at 2 sites, MboI cleaved it at 9 sites, and HpaI cleaved it at 17 sites. The sizes of the fragments produced by digestion with these enzymes were determined by using restriction fragments of T7 DNA as molecular weight standards. As a result of this analysis, the size of T3 DNA was estimated to be 38.74 kilobases. The fragments were ordered with respect to each other and to the genetic map to produce a restriction map of T3 DNA. The location and occurrence of the restriction sites in T3 DNA are compared with those in the DNA of the closely related bacteriophage T7.     

Arrangement of the genome of the human papovavirus RF virus.

DNA from plaque-purified RF virus, a variant of BK virus, was found to contain two species of molecules. Hybridization of each DNA species to the fragments of BK virus DNA revealed that one species had a deletion corresponding to at least 50% of the late region and the other had a deletion corresponding to at least 40% of the early region of BK virus DNA. Analysis by cleavage of each RF virus DNA species with restriction endonucleases EcoRI, HindIII, AvaII, and PvuII, when compared with BK virus DNA, revealed that the size and number of fragments were different. These results suggest the loss of some restriction sites and the appearance of new sites, probably as a result of base changes in each RF virus DNA species. Furthermore, analysis of the restriction map of each DNA molecule revealed in insertion(s) in both DNA species.     

Mapping and ordering of fragments of BK virus DNA produced by restriction endonucleases.

A total of 51 restriction sites were recognized within the BK virus genome by the combination of 10 different restriction endonucleases. These sites were mapped and oriented relative to one another as well as to the five fragments generated by the digestion of BK virus DNA with HindIII and EcoRI. The result was a comprehensive physical map suitable for in-depth characterization of the functions of BK virus at the molecular level.     

Physical mapping of BK virus DNA with SacI, MboII, and AluI restriction endonucleases.

A new restriction endonuclease, SacI from Streptomyces achromogenes cleaves BK virus (strain MM) DNA into 3 fragments, whereas MboII from Moraxella bovis and AluI from Arthrobacter luteus give 22 and 30 fragments, respectively. All these specific DNA fragments were ordered and mapped on the viral genome by two methods first, by the reciprocal digestion method using uniformly 32P-labeled DNA; and second, by the partial digestion technique using the single-end 32P-labeled DNA. This study, together with those reported earlier, defined the location of 90 cleavage sites on the BK virus DNA.     

Human cytomegalovirus DNA: BamHI, EcoRI and PstI restriction endonuclease cleavage maps

The cloned HindIII fragments of human cytomegalovirus (HCMV) strain AD169 DNA were mapped with respect to the BamHI, EcoRI and PstI restriction endonuclease cleavage sites. Composite restriction endonuclease cleavage maps for the entire virus genome were constructed using the previously established linkages between the HindIII fragments.     

Construction of a restriction map of bacteriophage T3 DNA

A restriction endonuclease cleavage map of bacteriophage T3 DNA has been constructed. The enzymes used and, within parentheses, the number of their cleavage sites on T3 DNA are: HindIII (1), XbaI (1), BglII (1), KpnI (2), MboI (9), and HpaI (17). The size and the relative location of each fragment have been established, defining an accurate physical map of T3 DNA.     

Cleavage map of the simian-virus-40 genome by the restriction endonuclease III of Haemopholus aegyptius.

Enzymic digestion of Simian virus 40 (SV40) DNA with Haemophilus aegyptius restriction endonuclease Hae III results in 10 major and eight minor fragments. These were resolved by electrophoresis on graduated polyacrylamide slab gels. All fragments have been characterized with respect to the size relative to the Haemophilus influenzae Rd fragments (Hind). They were ordered on the SV40 DNA map by means of overlap analysis of the double cleavage products derived from sequential digestion of Hind fragments with Hae III endonuclease and Hae fragments with Hind II + III enzyme, as well as by other reciprocal cleavage experiments, including those involving Haemophilus para-influenzae fragments. In this way the 18 Hae III cleavage sites and the 13 Hind sites have been localized on the circular SV40 DNA map.     

Comparative analysis of GS and BK virus genomes.

Analysis of heteroduplexing between the genomes of GS virus, a BK-group virus, and the prototype BK virus revealed one region of nonhomology. Further analysis by cleavage of viral DNA with the restriction endonucleases EcoRI, HindIII, and HaeIII revealed that base changes in the GS virus genome spanned 0.6 to 0.7 map unit from the EcoRI site. Large T and small t antigens of GS virus appear to be similar in size to the BK virus antigens.     

Adenine + thymine content of different genes located on the broad host range plasmid RP4

The genetic map of plasmid RP4 was correlated with its adenine+thymine (AT) map. For this purpose, RP4 DNA was digested with one or both of the restriction enzymes EcoRI and HindIII and the resulting linear RP4 molecules and fragments were partially denatured, examined in the electron microscope and their AT maps were determined using a computer program. From these AT maps the EcoRI and HindIII restriction sites were located on the AT map of RP4. Since the positions of these restriction sites on the genetic map of RP4 are known, the maps could be compared. They revealed a high AT content for the Tn1 transposon and the kanamycin resistance gene. The tra-1 region is also distinguished by a sharply defined AT-rich region, whereas tra-2 and the tetracycline resistance gene have an AT content which is not distinctly different from the average AT content of RP4.     

Linkage map of the fragments of herpesvirus papio DNA.

Herpesvirus papio (HVP), an Epstein-Barr-like virus, causes lymphoblastoid disease in baboons. The physical map of HVP DNA was constructed for the fragments produced by cleavage of HVP DNA with restriction endonucleases EcoRI, HindIII, SalI, and PvuI, which produced 12, 12, 10, and 4 fragments, respectively. The total molecular size of HVP DNA was calculated as close to 110 megadaltons. The following methods were used for construction of the map; (i) fragments near the ends of HVP DNA were identified by treating viral DNA with lambda exonuclease before restriction enzyme digestion; (ii) fragments containing nucleotide sequences in common with fragments from the second enzyme digest of HVP DNA were examined by Southern blot hybridization; and (iii) the location of some fragments was determined by isolating individual fragments from agarose gels and redigesting the isolated fragments with a second restriction enzyme. Terminal heterogeneity and internal repeats were found to be unique features of HVP DNA molecule. One to five repeats of 0.8 megadaltons were found at both terminal ends. Although the repeats of both ends shared a certain degree of homology, it was not determined whether they were identical repeats. The internal repeat sequence of HVP DNA was found in the EcoRI-C region, which extended from 8.4 to 23 megadaltons from the left end of the molecule. The average number of the repeats was calculated to be seven, and the molecular size was determined to be 1.8 megadaltons. Similar unique features have been reported in EBV DNA (D. Given and E. Kieff, J. Virol. 28:524-542, 1978).     

Biochemical studies on bovine adenovirus type 3. III. Cleavage maps of viral DNA by restriction endoncleases EcoRI, BamHI, and HindIII.

Cleavage of bovine adenovirus type 3 (BAV3) DNA by restriction endonucleases EcoRI, BamHI, and HindIII yielded 7 (A to G), 5 (A to E), and 12 (A to L) fragments, respectively. The order of these fragments has been determined to be GDACBFE for EcoRI fragments, AEBDC for BamHI fragments, and JEBKACDHFGIL for HindIII fragments, and cleavage sites of these enzymes have been mapped on the genome of BAV3. BAV3 preparation contains incomplete virus whose genome has a deletion of about 13% of complete virus genome. Restriction endonuclease digestion of the incomplete virus DNA revealed that EcoRI E and F, BamHI C and HindIII G, I, and L fragments were deleted. Therefore, the deleted region of incomplete virus DNA is located near the right-hand end of the BAV3 DNA molecule, a result consistent with our previous electron-microscopic observations on heteroduplex molecules formed between complete and incomplete BAV3 DNA.     

Physical map of the bacteriophage T5 genome based on the cleavage products of the restriction endonucleases SalI, SmaI, BamI, and HpaI.

A physical map of the bacteriophage T5 genome was constructed by ordering the fragments produced by cleavage of T5 DNA with the restriction endonucleases SalI (4 fragments), SmaI (4 fragments), BamI (5 fragments), and HpaI (28 fragments). The following techniques were used to order the fragments. (i) Digestion of DNA from T5 heat-stable deletion mutants was used to identify fragments located in the deletable region. (ii) Fragments near the ends of the T5 DNA molecule were located by treating T5 DNA with lambda exonuclease before restriction endonuclease cleavage. (iii) Fragments spanning other restriction endonuclease cleavage sites were identified by combined digestion of T5 DNA with two restriction endonucleases. (iv) The general location of some fragments was determined by isolating individual restriction fragments from agarose gels and redigesting the isolated fragments with a second restriction enzyme. (v) Treatment of restriction digests with lambda exonuclease before digestion with a second restriction enzyme was used to identify fragments near, but not spanning, restriction cleavage sites. (vi) Exonucleases III treatment of T5 DNA before restriction endonuclease cleavage was used to locate fragments spanning or near the natural T5 single-chain interruptions. (vii) Analysis of the products of incomplete restriction endonuclease cleavage was used to identify adjacent fragments.     

Restriction enzyme mapping of vaccinia virus DNA.

The cleavage sites for the restriction enzymes Bg/I, HindIII, KpnI, SalI, SmaI, and XhoI were located, from primary data, on the DNA isolated from the WR strain of vaccinia virus. Bg/I and SmaI divide the DNA into five segments which can be isolated by sucrose gradient centrifugation. These large segments provide a convenient means to group segments produced by other enzymes. The construction of physical maps was initiated by identifying the segments at each end of the DNA and then finding segments which were adjacent to these terminal sections. This was accomplished by isolating large shear fragments which contained the covalently linked termini of the DNA. Most of the data needed to derive the maps were obtained by isolating segments produce by one enzyme and then cleaving these individual segments with a second enzyme.     

A simple method for DNA restriction site mapping.

When a DNA molecule, enzymatically labelled with 32p at one end, is partially digested with a restriction enzyme labelled tdna fragments are obtained which form an overlapping series of molecules, all with a common labelled terminus. ta restriction map can then be constructed from an analysis of the size distribution of these molecules. This technique has been used for the restriction site mapping of cloned histone DNA (h22) where as many as 35 cleavage sites may be accurately determined in a single experiment.     

Restriction map of a capsule plasmid of Bacillus anthracis

The capsule plasmid pTE702 of Bacillus anthracis has been physically mapped with the restriction endonucleases HindIII, PstI, BamHI, SalI, and XhoI. A HindIII fragment map of pTE702 (96.5 kb) was obtained by analysis of the recombinant plasmids and cosmids containing overlapping fragments partially digested with HindIII. The physical map for PstI, BamHI, SalI, and XhoI was obtained by double digestion mapping of these sites in relation to the HindIII sites. The replication region of pTE702 was determined by in vitro genetic replicon labeling in B. subtilis.     

Restriction endonuclease mapping of the proviral DNA of the exogenous RIII murine mammary tumor virus

Cellular DNA containing integrated murine mammary tumor virus (MuMTV) was isolated from FeI/C6 feline kidney cells and CCL64 mink lung cells infected with milkborne RIII MuMTV. By using restriction enzyme HpaI, intact RIII MuMTV provirus (length, 8.7 kilobases [kb]) was excised from the cellular DNA. Subsequent restriction endonuclease analysis of this HpaI fragment with KpnI, HindIII, EcoRI, BamHI, BglII, PstI, SstI, SalI, and XhoI enabled us to construct a map of the RIII virus genome. A comparison of this map with the maps of the GR and C3H MuMTV's revealed that there are greater sequence differences between the RIII virus and the GR and C3H MuMTV proviruses than there are between the GR and C3H proviruses. The following are features of the restriction map unique to the RIII provirus: the presence of three BamHI and two EcoRI cleavage sites, a HpaI cleavage site in the terminal 3'-5' repeat unit of the provirus, and the absence of an XhoI cleavage site. Another distinguishing feature of the RIII provirus is that the sizes of some of the restriction fragments produced by cleavage of the RIII provirus with PstI are different from the sizes of the fragments obtained by PstI cleavage of the GR and C3H proviruses. Like the GR proviral DNA, the RIII proviral DNA has three SstI (SacI) cleavage sites, whereas the C3H provirus has only two SstI sites. HpaI digestion of MuMTV-infected mink lung cell DNA revealed only one class of provirus (an 8.7-kb fragment); however, we observed several minor classes of RIII proviral DNA in addition to the major class of provirus DNA in infected cat kidney cells. PstI digestion of the HpaI 8.7-kb fragments from both feline and mink cells generated a 3.7-kb DNA fragment identical in size to a PstI-generated fragment that has been found in GR and C3H milkborne virus-infected cells. Although a fragment similar in size to the milkborne 3.7-kb PstI fragment has been found as an endogenous component in many C3H and GR mouse tissues, we did not observe such an endogenous fragment in the RIII mouse strain. Therefore, the 3.7-kb fragment may be useful as a marker for the milkborne RIII MuMTV provirus in RIII mice.     

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。     

Simian adenovirus 20 genome. I. DNA mapping using restriction enconucleases BamHI, EcoRi, XbaI, HindIII

The effect of specific restriction endonuclease on the simian adenovirus SV20 DNA was studied. It was shown that endonucleases SalI, XbaI, EcoRI, BamHI, HindIII cleaved the viral DNA into 3, 4, 5, 5, 8 specific fragments respectively. The sequence of fragments (physical map) was determined and found to be B-C-A for enzyme SalI, C-D-B-A--for enzyme Xbal, E-A-C-D-B--for enzyme EcoRI, B-E-C-A-D--for enzyme BamHI and B-E-A-C-(GH)-D-F--for enzyme HindIII. The G-C content of specific fragments was studied. The "right"-"left" orientation of the physical map of the simian adenovirus 20 DNA based on the G-C content was made in respect with the nomenclature of human adenoviruses.     

Analysis of cellular integration sites in avian sarcoma virus infected duck embryo cells.

The cellular sites of integration of avian sarcoma virus (ASV) have been examined in clones of duck embryo cells infected with the Bratislava 77 strain of ASV using restriction endonuclease digestion, agarose gel electrophoresis, Southern blotting, and hybridization with labeled ASV complementary DNA probes. DNA prepared from 11 clones of duck embryo cells infected with the Bratislava 77 strain of ASV was digested with the restriction enzymes HpaI, which cleaves once within the viral genome, and Hind III, which cleaves twice within the viral genome, and the virus-cell DNA juncture fragments were resolved by agarose gel electrophoresis. Analysis of the virus-cell junctures present in individual ASV-infected duck embryo clones revealed that all clones contain at least one copy of nondefective proviral DNA with some clones containing as many as 5 to 6 copies of proviral DNA. A comparison of the virus-cell juncture fragments present in different ASV-infected clones showed that each clone contains a unique set of virus-cell junctures. These data suggest that ASV DNA can integrate at multiple sites within the duck embryo cell genome and that these sites appear to be different as defined by digestion with the restriction enzymes HpaI and HindIII.