Mechanical inoculation of Nicotiana tabacum with the PSTVd isolate KF 440-2 from the host plant tomato resulted in the de novo emergence, replication, and accumulation of a new "tobacco variant," designated PSTVd NT. It produces no symptoms in tobacco but, like PSTV KF 440-2, severe ones in tomato. The sequence analysis of PSTVd NT revealed a single nucleotide substitution from C-->U at position 259. Autonomous viroid replication was also induced in tobacco by genomic integration of oligomeric cDNA copies of PSTVd KF 440-2. Although these cDNAs contained the original tomato-specific C259, the circular PSTVd RNA subsequently accumulating in tobacco also exhibited the C259-->U259 substitution. In the secondary structure of PSTVd, nucleotide 259 is part of an internal loop analogous to loop E of eukaryotic 5S rRNA and presumed to be the only bulged extrahelical nucleotide of this loop. The C259 in PSTVd KF 440-2 and in practically all other isolates and the U259 in PSTVd NT of the loop E-like structure might be involved in protein binding and in viroid processing. The new variant PSTVd NT is genetically stable in both tobacco and tomato.
McrBC is a GTP-dependent restriction endonuclease of E. coli K12, selectively directed against DNA containing modified cytosine residues. McrB, one of its components, is responsible for the binding and, together with McrC, for the cleavage of DNAs containing two 5'-Pu(m)C sites separated by 40-80 base pairs. Gel retardation assays with wild-type and mutant McrB reveal that (i) single 5'-Pu(m)C sites in DNA can be sufficient to elicite binding by McrB. Binding to such substrates is, however, weak and strongly dependent on the sequence context of Pu(m)C sites. (ii) Strong DNA binding (K(ass) approximately 10(7)M[-1]) is dependent on the presence of at least two Pu(m)C sites, even if they are separated by less than 40 bp, and is modulated by the sequence context (-A(m)CCGGT- --> -A(m)CT(C/G)AGT- --> -AGG(m)CCT- --> -AAG(m)CTT-). (iii) DNA binding by McrB is accompanied by formation of distinct multiple complexes whose distribution is modulated by GTP. (iv) McrC, which cannot bind DNA by itself, moderately stimulates the DNA binding of McrB and converts McrB-DNA complexes to large aggregates. (v) Deletion of the C-terminal half of McrB, which harbors the three consensus sequences characteristic for guanine nucleotide binding proteins, leads to protein inactive in GTP binding and/or hydrolysis and in McrC-assisted DNA cleavage; the protein, however, remains fully competent in DNA binding. (vi) Mutations in McrB which lead to a reduction in GTP binding and/or hydrolysis can affect DNA binding, suggesting that the two activities are coupled in the full-length protein.
We describe a novel microfluidic perfusion system for high-resolution microscopes. Its modular design allows pre-coating of the coverslip surface with reagents, biomolecules, or cells. A poly(dimethylsiloxane) (PDMS) layer is cast in a special molding station, using masters made by photolithography and dry etching of silicon or by photoresist patterning on glass or silicon. This channel system can be reused while the coverslip is exchanged between experiments. As normal fluidic connectors are used, the link to external, computer-programmable syringe pumps is standardized and various fluidic channel networks can be used in the same setup. The system can house hydrogel microvalves and microelectrodes close to the imaging area to control the influx of reaction partners. We present a range of applications, including single-molecule analysis by fluorescence correlation spectroscopy (FCS), manipulation of single molecules for nanostructuring by hydrodynamic flow fields or the action of motor proteins, generation of concentration gradients, trapping and stretching of live cells using optical fibers precisely mounted in the PDMS layer, and the integration of microelectrodes for actuation and sensing.
The GTP-dependent restriction enzyme McrBC consists of two polypeptides: one (McrB) that is responsible for GTP binding and hydrolysis as well as DNA binding and another (McrC) that is responsible for DNA cleavage. It recognizes two methylated or hemimethylated RC sites (R(m)C) at a distance of approximately 30 to more than 2000 base pairs and cleaves the DNA close to one of the two R(m)C sites. This process is strictly coupled to GTP hydrolysis and involves the formation of high-molecular mass complexes. We show here using footprinting techniques, surface plasmon resonance, and scanning force microscopy experiments that in the absence of McrC, McrB binds to a single R(m)C site. If a second R(m)C site is present on the DNA, it is occupied independently by McrB. Whereas the DNA-binding domain of McrB forms 1:1 complexes with each R(m)C site and shows a clear footprint on both R(m)C sites, full-length McrB forms complexes with a stoichiometry of at least 4:1 at each R(m)C site, resulting in a slightly more extended footprint. In the presence of McrC, McrB forms high-molecular mass complexes of unknown stoichiometry, which are considerably larger than the complexes formed with McrB alone. In these complexes and when GTP is present, the DNA is cleaved next to one of the R(m)C sites at distances differing by one to five helical turns, suggesting that in the McrBC-DNA complex only a few topologically well-defined phosphodiester bonds of the DNA are accessible for the nucleolytic center of McrC.
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