Plant transformation by microinjection techniques

Several techniques have been developed for introducing cloned genes into plant cells. Vectorless delivery systems such as PEG-mediated direct DNA uptake (e.g. Pasz-kowski et al. 1984), electroporation (e.g. Shillito et al. 1985), and fusion of protoplasts with liposomes (Deshayes et al. 1985) are routinely used in many experiments (see several chapters of this issue). A wide range of plant species, dicotyledonous as well as monocotyledonous, has been transformed by these vectorless DNA transfer systems. However, the availability of an efficient protoplast regeneration system is a prerequisite for the application of these techniques. For cells with intact cell walls and tissue explants the biological delivery system of virulent Agrobacterium species has been routinely used (for review see Fraley et al. 1986). However, the host range of Agrobacterium restricts the plant species, which can be transformed using this vector system. In addition, all these methods depend on selection systems for recovery of transformants. Therefore a selection system has to be established first for plant species to be transformed. The microinjection technique is a direct physical approach, and therefore host-range independent, for introducing substances under microscopical control into defined cells without damaging them. These two facts differentiate this technique from other physical approaches, such as biolistic transformation and macroinjection (see chapters in this issue). In these other techniques, damaging of cells and random manipulation of cells without optical control cannot be avoided so far. In recent years microinjection technology found its application in plant sciences, whereas this technique has earlier been well established for transformation of animal tissue culture cells (Capecchi 1980) and the production of transgenic animals (Brin-ster et al. 1981, Rusconi and Schaffner 1981). Furthermore, different parameters affecting the DNA transfer via microinjection, such as the nature of microinjected DNA, and cell cycle stage, etc, have been investigated extensively in animal cells (Folger et al. 1982, Wong and Capecchi 1985), while analogous experiments on plant cells are still lacking.     

Role of carcinogen-modified deoxynucleotide precursors in mutagenesis

Agents which damage or modify cellular DNA will generally also modify the nucleotide precursor pools, sometimes preferentially (Topal and Baker, 1982). There are at least two different ways that incorporation of modified (possibly promutagenic) nucleotides could, theoretically, make a significant contribution to the mutations induced by these agents. Modified bases may exhibit ambiguous base pairing and produce mutations during normal replication or they may induce secondary mutations as a result of processing subsequent to incorporation. There are important precedents for such possibilities. Classical studies on mutagenesis with prototype mutagens like 2-aminopurine (2-AP) and 5-bromouracil clearly show that mutations can occur by incorporation of deoxynucleotides of tautomeric or ionized (Sowers et al., 1987) bases into newly synthesized DNA (Ronen, 1979; Lasken and Goodman, 1984, Coulondre and Miller, 1977). 5-Hydroxymethyl-2′-deoxyuridine (HMdU), a product of oxidative DNA damage, can also be (re)incorporated into cellular DNA with both toxic and mutagenic consequences (Kaufman, 1987; Shirname-More et al., 1987). Furthermore, modified nucleotides may alter the pool sizes of the normal nucleotides and indirectly produce toxic and mutagenic effects. However, these effects are generally see at high, nonphysiological, concentrations of the modified precursors and may not be relevant under physiological conditions. The relative importance of modified deoxynucleotide precursors in the production of mutations by alkylating and oxidative DNA-damaging agents is discussed.     

An analysis of the dynamics of mammalian mitochondrial DNA sequence evolution

The dynamics of the substitution process for mammalian mitochondrial DNA have been modeled. The temporal behavior of several quantities has been studied and the model's predictions have been compared with estimates obtained from recent mtDNA sequence data for an increasingly divergent series of primates, the mouse and the cow (Anderson et al. 1981, 1982; Bibb et al. 1981; Brown et al. 1982). The results are consistent with the hypothesis that the decrease in the proportion of transitions observed as divergence increases is a consequence of the highly biased substitution process. In addition, the results support the hypothesis that, although a portion of the mtDNA molecule evolves at an extremely rapid rate, a significant portion of the molecule is under strong selective constraints.      

An IS4 transposition causes a 13-bp duplication of phage lambda DNA and results in the constitutive expression of the cI and cro gene products

We have examined the nature of the additional DNA present in lambda hyp- mutants (Eisen et al., 1982). This DNA is an IS4 element in orientation I, in the y region of bacteriophage lambda at nucleotide position 39,139 (see Moore et al., 1979). Our assignment is based on (i) the similarity in size derived from the PstI, AvaI, and HindII restriction pattern and (ii) the DNA sequence of both the left and right lambda-IS4 DNA junctions in phage lambda hyp15rev4. The IS4 integration event resulted in the duplication of 13 bp of lambda DNA in contrast to the 11- and 12-bp duplications previously observed at the sites of IS4 integrations elsewhere (Klaer et al., 1981).     

Acid giemsa technique for rapid identification of mitotic cells

We developed a rapid technique for differential staining of compacted chromatin as a tool for screening of large tissue culture cell populations for mitotic cells. With a combination of acid Giemsa staining and counterstaining, differential staining of mitotic cells and classification according to stage of mitosis can be accomplished at magnifications as low as x 50-100 (objectives of x 5-10). The mapped and classified cells can then be de-stained and re-studied for DNA content by Feulgen staining and/or for uptake of radioactive DNA precursors by autoradiography. The staining and de-staining procedures outlined do not affect the reproducibility and accuracy of DNA content measurements or measurements of radioactive uptake. Therefore, this technique can be used for cell kinetic analysis by the percentage labeled mitoses method and for cytophotometric studies of mitotic segregation.     

Location and nucleotide sequence of a tobacco chlorophlast DNA segment capable of replication in yeast

Summary A 1.7 Kbp EcoRI fragment of Nicotiana tabacum chloroplast DNA cloned in YIp5, consisting of pBR322 and the yeast ura3 gene, possessed ars (autonomously replicating sequences) activity in Saccharomyces cerevisiae. This fragment was located in the small single copy region proximal to the 23S rRNA gene.Sequences responsible for potential ars activity were narrowed to about 350 base pairs, where clusters of nucleotides similar to a consensus sequence (11 bp) essential for several yeast ars (Broach et al. 1982), to the stem-and-loop structure typical of yeast ars3 (Feldmann et al. 1981), and regions surrounding the replication origin of mitochondrial DNAs of HeLa Cells (Crews et al. 1979) and yeast (de Zamaroczy et al. 1981) can be observed.Abbreviations ctDNA chloroplast DNA - Kbp kilobase pairs     

Polymorphism in the 5'-flanking region of the human insulin gene and the incidence of diabetes.

DNA length polymorphism in the 5'-flanking region of the human insulin gene has been reported by Bell et al. (1981), Rotwein et al. (1981), and Owerbach and Nerup (1982). Bgl I digestions of human DNA that have been hybridized to an insulin probe using the Southern technique shows that there are two distinct groups of 5'-flanking lengths: one being shorter than 3.6 kilobases (kb) and the other being longer than 4.3 kb. The insulin genes with the former length are denoted as A1, and those with the latter as A2. Using these data and demographic data of diabetes, it is estimated that, when the fitness of A1 A2 individual was taken as unity, the amounts of fitness reduction for A1 A1 was 6.5 X 10(-6) and that for A2 A2 was -5.6 X 10(-6). Because of these small magnitudes of selection, the changes in population incidences of insulin-dependent diabetes and noninsulin-dependent diabetes are not affected much by the polymorphism in the 5'-flanking region of the insulin gene.     

Deletion mapping of kil and kor functions in the trfA and trfB regions of broad host range plasmid RK2

Figurski et al. (1982) have reported that certain loci on the broad host range plasmid RK2 (kil functions) can be cloned only in the presence of other trans-acting segments of the plasmid genome (kor functions). They have suggested that the presence of these functions may in part account for the structure of mini RK2 replicons which were constructed in order to define the regions of the plasmid which encode replication/maintenance functions (Thomas et al. 1980). We have therefore investigated the relationship between these two sets of kil and kor loci and the loci implicated in the replication/maintenance of RK2. We find that, whilst the three kil loci reported by Figurski et al. (1982) are absent from these derivatives, a fourth such locus (kilD) is closely linked to trfA, a gene essential for RK2 replication. The kilD locus was probably responsible for the inclusion in mini replicons of a segment of RK2 DNA which carries both korD and korA in addition to trfB, a gene defined by a temperature-sensitive maintenance defect, but which can be deleted leaving a functional RK2 replicon (Thomas 1981 b). The kilB locus is situated on the opposite side of kilD from trfA, all three loci lying within a 3.6 kb segment of RK2 DNA. The korA, korD and trfB functions all map within a 900 bp segment of DNA, while korB requires sequence information at least 1.5 kb from this segment.     

Radiation-induced DNA single-strand breaks in freshly isolated human leukocytes.

Single-strand breaks are a major form of DNA damage caused by ionizing radiation, and measurement of strand breaks has long been used as an index of overall cellular DNA damage. Most assays for DNA single-strand breaks in cells rely on measuring fractionated DNA samples following alkali denaturation. Quantification is usually achieved by prelabeling cells with radioactive DNA precursors; however, this is not possible in the situation of nondividing cells or freshly isolated tissue. It has previously been demonstrated that the alkali unwinding assay of DNA strand breaks can be quantified by blotting the recovered DNA on nylon membranes and hybridizing with radiolabeled sequence-specific probes. We report here improvements to the technique, which include hot alkali denaturation of DNA samples prior to blotting and the use of carrier DNA that is non-complementary to the radiolabeled probe. Our method allows both single- and double-stranded DNA to be quantified with the same efficiency, thereby improving the sensitivity and reproducibility of the assay, and allows calibration for determination of absolute levels of DNA strand breaks in cells. We also used this method to assay radiation-induced DNA strand breaks in freshly isolated human leukocytes and found them to have a strand break induction rate of 1815 strand breaks/cell/Gy.     

Detection and characterization of Tn2501, a transposon included within the lactose transposon Tn951

The DNA sequence spanning coordinates 9.9 to 16.4 kilobases of the lactose transposon Tn951 ( Cornelis et al., Mol. Gen. Genet. 160:215-224, 1978) constitutes a transposable element by itself. Unlike Tn951 ( Cornelis et al., Mol. Gen. Genet. 184:241-248, 1981), this element, called Tn2501 , transposes in the absence of any other transposon. Transposition of Tn2501 proceeds through transient cointegration and duplicates 5 base pairs of host DNA. Tn2501 is flanked by nearly perfect inverted repeats (44 of 48), related to the inverted repeats of Tn21 ( Zheng et al., Nucleic Acids Res. 9:6265-6278, 1982). Unlike Tn21 , Tn2501 does not confer mercury resistance.     

Epstein-Barr virus DNA XII. A variable region of the Epstein-Barr virus genome is included in the P3HR-1 deletion.

The P3HR-1 subclone of Jijoye differs from Jijoye and from other Epstein-Barr virus (EBV)-infected cell lines in that the virus produced by P3HR-1 cultures lacks the ability to growth-transform normal B lymphocytes (Heston et al., Nature (London) 295:160-163, 1982; Miller et al., J. Virol. 18:1071-1080, 1976; Miller et al., Proc. Natl. Acad. Sci. U.S.A. 71:4006-4010, 1974; Ragona et al., Virology 101:553-557, 1980). The P3HR-1 virus was known to be deleted for a region which encodes RNA in latently infected, growth-transformed cells (Bornkamm et al., J. Virol. 35:603-618, 1980; Heller et al., J. Virol. 38:632-648, 1981; King et al., J. Virol. 36:506-518, 1980; Raab-Traub et al., J. Virol. 27:388-398, 1978; van Santen et al., Proc. Natl. Acad. Sci. U.S.A. 78:1930-1934, 1980). This deletion is now more precisely defined. The P3HR-1 genome contains less than 170 base pairs (and possibly none) of the 3,300-base pair U2 region of EBV DNA and is also lacking IR2 (a 123-base pair repeat which is the right boundary of U2). A surprising finding is that EBV isolates vary in part of the U2 region. Two transforming EB viruses, AG876 and Jijoye, are deleted for part of the U2 region including most or all of a fragment, HinfI-c, which encodes part of one of the three more abundant cytoplasmic polyadenylated RNAs of growth-transformed cells (King et al., J. Virol. 36:506-518, 1980; King et al., J. Virol. 38:649-660, 1981; van Santen et al., Proc. Natl. Acad. Sci. U.S.A. 78:1930-1934).     

Epidermal cell migration on laminin-coated substrates

Summary Pieces of coverslip glass coated with various proteins were implanted under one edge of a fresh skin wound on adult newt hind limbs so that the implant served as wound bed for the migrating wound epithelium. Laminin, a protein that has been implicated as an epithelial-specific adhesin, was a moderately good migration substrate. Type-IV collagen, fibrinogen and fibronectin, however, were significantly better. Fetuin, myoglobin, and casein all proved to be very poor substrates, allowing practically no migration. The inability of fetuin, myoglobin, and casein to support migration is further evidence that the considerable migration that occurs on collagen (Donaldson et al. 1982) fibrinogen and fibronectin (Donaldson and Mahan 1983) and the moderate migration on laminin, is a relatively specific response to these proteins and is therefore of special significance. The fact that laminin is a poorer migration substrate than collagen, fibrinogen or fibronectin suggests that the absence of cell surface laminin that has been associated with epithelial movement in several studies (Stanley et al. 1981; Clark et al. 1982; Madri and Stenn 1982; Gulati et al. 1983) may promote motility by allowing epithelial cells to interact directly with other extracellular macromolecules.     

Molecular cloning of cDNA from foot-and-mouth disease virus C1-Santa Pau (C-S8). Sequence of protein-VP1-coding segment

cDNA segments copied from the RNA of foot-and-mouth disease virus (FMDV) C₁-Santa Pau (isolate C-S8) have been cloned in plasmid pBR322. A 998-bp DNA fragment, that includes the region coding for capsid protein VP1, the carboxy terminus of VP3, and the amino terminus of precursor protein p52 has been sequenced. Comparison of the nucleotide sequence with those from FMDV O₁K, A₁₀61, a₁₂ and C₃ Indaial (Kurz et al., Nucl. Acids Res. 9 (1981) 1919–1931; Kleid et al., Science 214 (1981) 1125–1129; Boothroyd et al., Gene 17 (1982) 153–161; Makoff et al., Nucl. Acids Res. 10 (1982) 8285–8295) indicates extensive variability between the corresponding gene segments, including short insertions and deletions. Base transversions are more frequent than transitions within the VP1 coding segment, but not in the sequence coding for the amino-terminal end of p52. The nucleotide sequence divergence is reflected in variability in both the primary and the predicted higher-order structures of the encoded VP1s.     

Drosophila chk2 plays an important role in a mitotic checkpoint in syncytial embryos

Drosophila chk2 (Dmchk2, also called Dmnk) plays a crucial role in the DNA damage response pathway mediating cell cycle arrest and apoptosis [Xu et al., FEBS Lett. 508 (2001) 394-398; Peters et al., Proc. Natl. Acad. Sci. USA 99 (2002) 11305-11310]. In this study, the role of Dmchk2 in early embryogenesis was investigated. In the absence of Dmchk2 function, abnormal nuclei accumulate in the cortex of the syncytial embryo. We show that the abnormal nuclei result from a failure of chromosome segregation probably due to damaged or incomplete replicated DNA. Importantly, this Dmchk2 phenotype is partially suppressed by reducing the gene dosage of polo or stg. As Polo-like kinase was shown to colocalize and coimmunoprecipitate with Chk2 [Tsvetkov et al., J. Biol. Chem. 278 (2003) 8468-8475] in mammals, these observations suggest that polo might be a key target of Dmchk2 in regulating mitotic entry in response to DNA damage or replication block.     

The lactose permease of Escherichia coli: evidence in favor of a dimer

Lactose permease from Escherichia coli T 206 was purified in octyl-beta-D-glucopyranoside (octyl-glucoside) according to Newman et al. [J. Biol. Chem. (1981) 256, 11804-11808]. In this detergent the protein has a very high tendency to aggregate nonspecifically. Therefore, exchange of octyl-glucoside was performed for another nonionic detergent, dodecyl octaethylene glycol monoether (C12E8), in which the protein is more stable. The amounts of bound C12E8 and phospholipids were measured using radioactive detergent and gas chromatography, respectively, and were found to be respectively 0.2 and 0.15 g/g protein. Analytical ultracentrifugation (sedimentation velocity and sedimentation equilibrium) and gel filtration (conventional and high performance liquid chromatography) experiments indicated that in this detergent the lactose permease existed mainly as a dimer. This result is at variance with the monomeric state of the protein reported by Wright et al. [FEBS Lett. (1983) 162, 11-15] in another nonionic detergent (dodecyl-o-beta-maltoside). We discuss the possible reason for this discrepancy and suggest that the dimeric state of association may well reflect the situation that prevails in the membrane.     

Isolation of a D-genome specific repeated DNA sequence fromAegilops squarrosa

Three repeated sequence clones, pAS1(1.0 Kb), pAS2(1.8 Kb) and pAS12(2.5 Kb), were isolated fromAegilops squarrosa (Triticum tauschii). The inserts of the three clones did not hybridize to each other. Two of the clones, pAS2 and pAS12, contain repeated sequences which were distributed throughout the genome. The clone pAS1 sequence was more restricted and was located in specific areas on telomeres and certain interstitial sites along the chromosome length. This cloned sequence was also found to be restricted to the D genome at the level ofin situ hybridization. The pAS1 sequence will be useful in chromosomal identification and phylogenetic analysis. All three clones will allow assessment of genome plasticity inAegilops squarrosa. Nuclear DNA content varies over a range of 10,000 fold among all organisms (Nagl et al., 1983). Among angiosperms, at least a 65-fold range in genome size occurs in diploid species (Sparrow, Price and Underbrink, 1972; Bennett, Smith and Heslop-Harrison, 1982). This DNA variation has been reported within families, genera, and species (Rothfels et al., 1966; Rees and Jones, 1967; Miksche, 1968; Price, Chambers and Bachmann, 1981). Much of the interspecific variation in genome size among angiosperms appears to be due to amplification and/or deletion of DNA within chromosomes. The variation in genome size does not appear to result in changes in the number of coding genes (Nagl et al., 1983). While the number of coding genes, with the exception of rDNA in specific examples, appears to remain constant, the remaining non-coding regions are quite flexible. This non-coding DNA encompasses over 99% of the plant genome and consists of sequences that exist as multiple copies throughout the genome and are identified as repeated DNA sequences (Flavell et al., 1974). Flavell et al. (1974) have reported that increasing genome size in higher plants is associated with increasing repetitive DNA amounts. Subsequent reports have substantiated this correlation (Bachmann and Price, 1977; Narayan, 1982). In various cereals, heterochromatin, which has been demonstrated to be correlated with the location of specific repeated DNA sequences, has been positively correlated with genome size (Bennett, Gustafson and Smith, 1977; Rayburn et al., 1985). Furuta, Nishikawa and Makino (1975) found significant DNA content variation among different accessions ofAegilops squarrosa L. This species contains the D genome, a pivotal genome in several polyploid species and also found in hexaploid wheat (AABBDD). The importance of this genome to the study of bread wheat genomes makes the mechanism(s) of this genomic plasticity of particular interest. In order to determine which sequences are varying, one must first have a way to identify specific types of chromatin and/or DNA. Specific types of chromosome banding such as C- and N-banding have been used to identity types of chromatin in previous studies. C-banding of the D genome results in very lightly staining bands whose pattern is somewhat indistinct. N-banding alternatively has been shown to be useful in identifying certain chromosomes of hexaploid wheat but is limited by the lack of major bands in the D genome (Endo and Gill, 1984). Specific DNA sequences have been isolated fromTriticum aestivum cultivar “Chinese Spring” (hexaploid wheat). However, these sequences are representatives of the A and/or B genomes of hexaploid wheat and are not found in significant quantities in the D genome (Hutchinson and Lonsdale, 1982). Various other repeated DNA sequences have been successfully isolated from rye (Bedbrook et al., 1980) and identified on rye chromosomes (Appels et al., 1981; Jones and Flavell, 1982). Certain of these sequences are found in wheat genomes, but the sequences are representative of only a minor fraction of the D genome (Bedbrook et al., 1980; Rayburn and Gill, 1985). The purpose of this report is to describe three distinct repeated DNA sequences isolated fromA. squarrosa (D genome). Two clones appear to be distributed throughout the total genome, and the third clone is restricted to specific sites along the chromosomes. This latter clone will prove useful in cytologically defining the D genome chromosomes. These sequences appear representative of two types of repeated DNA genome organization: 1) sequences distributed throughout the genome and 2) specific arrays of repeated sequences. The availability of such repeated DNA sequence clones along with the known intraspecific DNA content variation inA. squarrosa will allow the study of genomic plasticity of this species.     

Silver staining of DNA restriction fragments for the ultrarapid identification of pseudorabies virus strains.

Restriction endonuclease analysis of pseudorabies virus DNA has been used to study various virus strains. To make use of a rapid technique for the identification of viral strains, studies have been undertaken to facilitate purification of the DNA from viral particles present in cytoplasmic fractions. The ultrasensitive photochemical silver staining of nucleic acid, described by Beidler et al. (Analytic Biochemistry 1982: 126) has been adapted and applied to the detection of pseudorabies virus restriction fragments. In a period of 5 h more than 1 microgram of DNA can be extracted from a 25 cm2 plastic flask containing infected cells and purified without ultra centrifugation. Low molecular weight DNA was separated from high molecular weight DNA by polyacrylamide gel electrophoresis. The restriction fragments were selectively visualized by silver staining which can detect 0.025 micrograms of total pseudorabies virus DNA. The electrophoretic DNA pattern of vaccine and wild strains has been studied using these techniques and the results agree with previously published data.     

DNAase I hypersensitive sites may be correlated with genomic regions of large structural variation

Helical-twist, roll and torsion-angle variations calculated by the Calladine (1982)-Dickerson (1983) rules were scanned along several nucleotide sequences for which DNAase I cleavage data are available. It has been shown that for short synthetic oligomers DNAase I cuts preferentially at positions of high helical twist (Dickerson & Drew, 1981; Lomonossoff et al., 1981). Our calculations indicate that DNAase I sensitive and hypersensitive sites in chromatin are correlated with regions of successive, large, helical-twist angle variations from regular B-DNA. In many cases these regions exhibit large variations in base-pair roll and backbone torsion angles as well. It has been suggested that DNAase I cuts in the vicinity of cruciforms. However, it was recently demonstrated by Courey & Wang (1983) and Gellert et al. (1983) that such cruciform formation in a negatively supercoiled DNA is kinetically forbidden under physiological conditions. We thus propose that clustering of large twist-angle (and/or roll and backbone torsion angle) variations may be among the conformational features recognized by the enzyme. Specific cuts can then preferentially occur at base-pair steps with high helical twists.     

Quantitative protein sequencing using mass spectrometry: thermally induced formation of thiohydantoin amino acid derivatives from N-methyl- and N-phenylthiourea amino acids and peptides in the mass spectrometer

A simple technique is described for continuous labeling of mammalian DNA with radioactive precursors adsorbed onto activated charcoal and administered by a single intraperitoneal injection. It is shown that adsorbed labeled thymidine is available in the organism for incorporation into DNA for at least 50 hr.The same technique can be used to substitute up to 20% of the thymidine with 5-bromodeoxyuridine in regenerating rat liver.     

A review and appraisal of the DNA damage theory of ageing

Given the central role of DNA in life, and how ageing can be seen as the gradual and irreversible breakdown of living systems, the idea that damage to the DNA is the crucial cause of ageing remains a powerful one. DNA damage and mutations of different types clearly accumulate with age in mammalian tissues. Human progeroid syndromes resulting in what appears to be accelerated ageing have been linked to defects in DNA repair or processing, suggesting that elevated levels of DNA damage can accelerate physiological decline and the development of age-related diseases not limited to cancer. Higher DNA damage may trigger cellular signalling pathways, such as apoptosis, that result in a faster depletion of stem cells, which in turn contributes to accelerated ageing. Genetic manipulations of DNA repair pathways in mice further strengthen this view and also indicate that disruption of specific pathways, such as nucleotide excision repair and non-homologous end joining, is more strongly associated with premature ageing phenotypes. Delaying ageing in mice by decreasing levels of DNA damage, however, has not been achieved yet, perhaps due to the complexity inherent to DNA repair and DNA damage response pathways. Another open question is whether DNA repair optimization is involved in the evolution of species longevity, and we suggest that the way cells from different organisms respond to DNA damage may be crucial in species differences in ageing. Taken together, the data suggest a major role of DNA damage in the modulation of longevity, possibly through effects on cell dysfunction and loss, although understanding how to modify DNA damage repair and response systems to delay ageing remains a crucial challenge.