Physico–Chemical and Bio-Chemical Studies on Some Mn (II) ion chelates with Physiological active Mixed Ligands

Some air stable electrolytic and non-electrolytic mixed ligand complexes of Mn(ll) ion with isonicotinic acid hydrazide have been synthesized and characterized by various physico chemical data based on micro analytical analysis, magnetic measurement, conductivity measurement, near and far infrared and electronic spectrophotometric studies. Various vibrational and spectral bands of ligand and complexes were studied and compared. The mode of shifting were used to diagnose the coordinating behaviour of donor element of ligand with Mn (ll) ions. All complexes were screened against Aspergillus flavus and classified as a mixed fungicide. Tentative octahedral geometry has been assigned for all Mn (ll)complexes

Complex intron generation in the yeast genus Lipomyces

In primary transcripts of eukaryotic nuclear genes, coding sequences are often interrupted by U2-type introns. Such intervening sequences can constitute complex introns excised by consecutive splicing reactions. The origin of spliceosomal introns is a vexing problem. Sequence variation existent across fungal taxa provides means to study their structure and evolution. In one class of complex introns called [D] stwintrons, an (internal) U2 intron is nested within the 5'-donor element of another (external) U2 intron. In the gene for a reticulon-like protein in species of the ascomycete yeast genus Lipomyces, the most 5' terminal intron position is occupied by one of three complex intervening sequences consistent of differently nested U2 intron units, as demonstrated in L. lipofer, L. suomiensis, and L. starkeyi. In L. starkeyi, the donor elements of the constituent introns are abutting and the complex intervening sequence can be excised alternatively either with one standard splicing reaction or, as a [D] stwintron, by two consecutive reactions. Our work suggests how [D] stwintrons could emerge by the appearance of new functional splice sites within an extant intron. The stepwise stwintronisation mechanism may involve duplication of the functional intron donor element of the ancestor intron.

Efficient CsSnI3-based inorganic perovskite solar cells based on a mesoscopic metal oxide framework via incorporating a donor element

A significantly improved oxidation stability of CsSnI3 perovskites was achieved by introducing cobaltocene as an electron donor additive.

High Frequency cDNA Recombination of the Saccharomyces Retrotransposon Ty5: The LTR Mediates Formation of Tandem Elements

Retroelement cDNA can integrate into the genome using the element-encoded integrase, or it can recombine with preexisting elements using the recombination system of the host. Recombination is a particularly important pathway for the yeast retrotransposon Ty5 and accounts for ∼30% of the putative transposition events when a homologous substrate is carried on a plasmid and ∼7% when the substrate is located at the chromosomal URA3 locus. Characterization of recombinants revealed that they are either simple replacements of the marker gene or tandem elements. Using an assay system in which the donor element and recombination substrates are separated, we found that the long terminal repeats (LTRs) are critical for tandem element formation. LTR-containing substrates generate tandem elements at frequencies more than 10-fold higher than similarly sized internal Ty5 sequences. Internal sequences, however, facilitate tandem element formation when associated with an LTR, and there is a linear relationship between frequencies of tandem element formation and the length of LTR-containing substrates. We propose that recombination is initiated between the LTRs of the cDNA and substrate and that internal sequences promote tandem element formation by facilitating sequence alignment. Because of its location in subtelomeric regions, recombinational amplification of Ty5 may contribute to the organization of chromosome ends.

Efficient and dispersed local P element transposition from Drosophila females.

We have investigated how Drosophila P element insertions are distributed in the chromosomal region near their starting site. A single P element residing in the euchromatin of minichromosome Dp1187 was mobilized following a cross to the delta 2-3 (99B) strain, and progeny bearing transpositions were identified with a minimum of bias by performing Southern blots on progeny. Approximately 1-2% of all progeny minichromosomes contained new insertions. Many of these "local transpositions" landed very close to or within the starting P element; however, nearly 1% of all progeny chromosomes contained new insertions 1-180 kb from the donor element. More local insertions were observed in the progeny of females than from male parents, and most occurred in a preferred orientation relative to the starting element. These observations suggested that donor elements are frequently excised and reinserted locally without ever dissociating from a transposition complex. The high frequency and diverse distribution of local transpositions recovered from females suggested that the efficiency of insertional mutagenesis can be significantly enhanced by using a starting P element(s) located near the target of interest.