5-Azacytidine increases the activity of neomycin phosphotransferase II in transgenic Nicotiana tabacum: A posttranslational mechanism may play a role

In previous studies, tobacco protoplasts were transformed with the bacterial gene encoding neomycin phosphotransferase II (NPT II). Transformed calluses lost neomycin phosphotransferase II activity after several subcultures. Treatment of calluses with 5-azacytidine, a demethylating agent, restored enzyme activity, suggesting that methylation of npt II sequences might be responsible for loss of NPT II activity. Studies presented here were designed to test that hypothesis. Results indicated that the effect of 5-azacytidine could not be blocked by the DNA replication inhibitor, hydroxyurea, nor by the 5-azacytidine analogue, cytidine as would be expected with a DNA demethylation mechanism. The level of NPT II mRNA was not increased by 5-azacytidine. Treatment with cycloheximide, a protein synthesis inhibitor, had no effect on 5-azacytidine-increased NPT II activity. There was no increase of NPT II protein caused by 5-azacytidine, whereas 5-azacytidine increased activity of NPT II. In contrast, the auxin 2,4-D increased both the NPT II protein and activity. Assays for malate dehydrogenase demonstrated that the effect of 5-azacytidine and hydroxyurea on NPT II was not due to an overall effect on callus metabolism. In vitro studies involving standard bacterial NPT II enzyme and crude extracts from untreated and 5-azacytidine- or hydroxyurea-treated calluses showed that the activity of NPT II added to the untreated extracts was lower than the activity of NPT II added to the extracts from calluses treated with 5-azacytidine or hydroxyurea, indicating that there was an unknown factor (or factors) in callus extracts which affected the activity of NPT II and itself was affected by 5-azacytidine and hydroxyurea treatment. These results suggested that one effect of 5-azacytidine in increasing NPT II activity was posttranslational.Abbreviations ELISA enzyme-linked immunosorbent assay - NOS nopalene synthase - nos DNA segment encoding NOS - NPT II neomycin phosphotransferase - npt II DNA segment encoding NPT II - PAGE polyacrylamide gel electrophoresis     

RFLP tagging of a salt tolerance gene in rice

A salt tolerant rice mutant (M-20) was obtained through selection in vitro. Its tolerance was stably inherited over eight generations and most traints between M-20 and its sensitive original 77–170 (Oryza sativa) were very similar. By deriving an F₂ population of M-20 × 77–170 and splitting every F₂ individual into two parts, with one part planted in normal conditions and another part in saline conditions, the inheritance of salt tolerance in rice was studied. Under normal conditions, there was no apparent segregation among F₂ individuals. Under saline conditions, however, the segregation of traits was obvious. According to our standards, the ratio of salt sensitive:moderately-tolerant:tolerant plants was 25:42:18, in accordance with a 1:2:1 ratio. It suggested that the improvement of salt tolerance in our materials was induced by the mutation of a major tolerant gene which showed incomplete dominance. By use of 130 RFLP probes distributed throughout the rice genome, the gene was tagged by a single copy DNA probe, RG4, which was located on chromosome 7. The genetic distance between the salt tolerant gene and RG4 was 7.0 ± 2.9 cM. Based on the split method, a method which could be currently used to evaluate the damage of salt stress in rice was proposed.     

A BC200-derived element and Z-DNA as structural markers in annexin I genes: Relevance to Alu evolution and annexin tetrad formation

We have identified two types of structural elements in genomic DNA for annexin I that provide physical evidence of genetic events leading to conserved changes in gene structure. The sequence upstream of the transcribed region in human annexin I contained a rare, Alu-like repetitive element with flanking direct repeats, probably derived from the active BC200 gene via germline retroposition. Nucleotide substitutions in this BC200 insert relative to the 7SL gene and its absence in rodent annexins I identified it as a recent primate pseudogene. Phylogenetic analysis showed that the BC200 gene represents a new clade of primate Alu evolution that branched near the time of appearance of the progenitor to the free left Alu monomer, FLAM-C. Separate analysis identified a Z-DNA motif in pigeon annexin I intron 7 that may represent the vestigial recombination site involved in primordial assembly of the annexin tetrad. These distinct structural features in annexin I genes provide insight into the evolution of Alu repeats and the mechanism of annexin tetrad formation.     

Molecular cloning and complete nucleotide sequence of the repeated unit and flanking gene of the scallop Pecten maximus mitochondrial DNA: Putative replication origin features

In the bivalve mollusc Pecten maximus, the size of the mitochondrial DNA molecules ranges from 20 to 25.8 kbp. This variability is mainly correlated with the occurrence of a variable domain composed with two to five 1.6-kbp repeated units tandemly arrayed in the genome. DNA fragments spanning the 1,586-base-pair-long repeated element and the nearest flanking gene have been cloned and sequenced. This sequence was analyzed regarding its base composition and potential secondary structures. The repeated unit domain was positioned and oriented with regard to the known flanking gene. It ends 2 base pairs upstream relative to the beginning of the tRNA^gly gene. The peculiar properties of the repeated unit were compared with those of the 1,442-bp repeated element found in the mitochondrial genome of the deep sea scallop Placopecten magellanicus. This comparison provided evidence for the absence of nucleotide conservation, except for a small sequence engaged in a secondary structure, but argued for a strong pressure maintaining domains with specific nucleotide content. A possible role for the conserved sequence is discussed.Correspondence to: A. Rigaa     

Nuclear counterparts of the cytoplasmic mitochondrial 12S rRNA gene: A problem of ancient DNA and molecular phylogenies

Monkey mummy bones and teeth originating from the North Saqqara Baboon Galleries (Egypt), soft tissue from a mummified baboon in a museum collection, and nineteenth/twentieth-century skin fragments from mangabeys were used for DNA extraction and PCR amplification of part of the mitochondrial 12S rRNA gene. Sequences aligning with the 12S rRNA gene were recovered but were only distantly related to contemporary monkey mitochondrial 12S rRNA sequences. However, many of these sequences were identical or closely related to human nuclear DNA sequences resembling mitochondrial 12S rRNA (isolated from a cell line depleted in mitochondria) and therefore have to be considered contamination. Subsequently in a separate study we were able to recover genuine mitochondrial 12S rRNA sequences from many extant species of nonhuman Old World primates and sequences closely resembling the human nuclear integrations. Analysis of all sequences by the neighbor-joining (NJ) method indicated that mitochondrial DNA sequences and their nuclear counterparts can be divided into two distinct clusters. One cluster contained all temporary cytoplasmic mitochondrial DNA sequences and approximately half of the monkey nuclear mitochondriallike sequences. A second cluster contained most human nuclear sequences and the other half of monkey nuclear sequences with a separate branch leading to human and gorilla mitochondrial and nuclear sequences. Sequences recovered from ancient materials were equally divided between the two clusters. These results constitute a warning for when working with ancient DNA or performing phylogenetic analysis using mitochondrial DNA as a target sequence: Nuclear counterparts of mitochondrial genes may lead to faulty interpretation of results.Correspondence to: A.C. van der Kuyl     

Identification of two Drosophila TGF-β family members in the grasshopper Schistocerca americana

Intercellular signaling molecules of the transforming growth factor- (TGF-) superfamily are required for pattern formation in many multicellular organisms. The decapentaplegic (dpp) gene of Drosophila melanogaster has several developmental roles. To improve our understanding of the evolutionary diversification of this large family we identified dpp in the grasshopper Schistocerca americana. S. americana diverged from D. melanogaster approximately 350 million years ago, utilizes a distinct developmental program, and has a 60-fold-larger genome than D. melanogaster. Our analyses indicate a single dpp locus in D. melanogaster and S. americana, suggesting that dpp copy number does not correlate with increasing genome size. Another TGF- superfamily member, the D. melanogaster gene 60A, is also present in only one copy in each species. Comparison of homologous sequences from D. melanogaster, S. americana, and H. sapiens, representing roughly 900 million years of evolutionary distance, reveals significant constraint on sequence divergence for both dpp and 60A. In the signaling portion of the dpp protein, the amino acid identity between these species exceeds 74%. Our results for the TGF- superfamily are consistent with current hypotheses describing gene duplication and diversification as a frequent response to high levels of selective pressure on individual family members.     

Repetitive DNA sequences located in the central region of the human mdr1 (multidrug resistance) gene may account for a gene fusion event during its evolution

The mdr1 gene, first member of the human multidrug-resistance gene family, is a major gene involved in cellular resistance to several drugs used in anticancer chemotherapy. Its product, the drug-excreting P-glycoprotein, shows a bipartite structure formed by two similar adjacent halves. According to one hypothesis, the fusion of two related ancestral genes during evolution could have resulted in this structure. The DNA sequence analysis of the introns located in the region connecting the two halves of the human mdr1 gene revealed a highly conserved poly(CA) · poly (TG) sequence in intron 15 and repeated sequences of the Alu family in introns 14 and 17. These repeated sequences most likely represent molecular fossils of ancient DNA elements which were involved in such a recombination event. Correspondence to: M. Pauly     

Pertussis Toxin-Sensitive G Protein α-Subunits: Production of Monoclonal Antibodies and Detection of Differential Increases on Differentiation of PC12 and LA-N-5 Cells

Abstract: Monoclonal antibodies were produced that are specific for the three major pertussis toxin-sensitive G protein α-subunits present in mammalian brain—αo, αi1, and αi2—using purified bovine brain G proteins, purified rat brain G proteins, and purified recombinant αi2, respectively. These monoclonal antibodies were used to monitor changes in the concentrations of the three G protein α-subunits during differentiation of PC12 cells and human neuroblastoma LA-N-5 cells. In PC12 cells, levels of αi1 but not αi2 increased during nerve growth factor-induced differentiation. In contrast, αi2 but not αi1 increased when LA-N-5 cells were differentiated with retinoic acid. The concentration of αo increased in both cell lines during differentiation. Electrophoretic resolution of αo subtypes revealed that although αo2 was the major subtype in undifferentiated cells, only the concentration of αo1 increased during differentiation of both PC12 and LA-N-5 cells. The level of 43-kDa growth-associated protein, a protein known to associate with αo, increased similarly to that of αo1. ADP-ribosylation of αo, αi1, and αi2 with pertussis toxin did not alter the reactivities of the monoclonal antibodies, but toxin treatment of cells reduced the concentrations of each protein after 24 h. There was no change in the concentration of αq, which is not ADP-ribosylated by pertussis toxin. Thus, these new monoclonal antibodies enabled the detection of differential increases in subtypes of αi and αo associated with neuronal differentiation.     

The UDP-Galactose:Ceramide Galactosyltransferase: Expression Pattern in Oligodendrocytes and Schwann Cells During Myelination and Substrate Preference for Hydroxyceramide

Abstract: Galactosylceramide ("galactocerebroside"; GalC) is a major glycolipid in the myelin sheath of the CNS and the PNS. The enzyme UDP-galactose:ceramide galactosyltransferase (CGalT) catalyzes the final step of the synthesis of GalC: the transfer of galactose to ceramide. By a differential screening approach, we have isolated a cDNA, the sequence of which is identical to the recently isolated cDNA clones for CGalT. By northern analysis and in situ hybridization we demonstrated that CGalT mRNA is expressed at birth in oligodendrocytes and Schwann cells, an expression pattern corresponding to the onset of myelination. In addition to the high expression levels of CGalT in oligodendrocytes and Schwann cells, in situ hybridization also showed expression in subtypes of neurons in spinal cord, cerebellum, and brainstem in the adult CNS, but at a much lower level than in oligodendrocytes. Expression of CGalT in COS cells demonstrated that CGalT has a preference for hydroxyceramide as a substrate. CGalT-expressing COS cells synthesize and transport GalC to their cell surface as shown by immunofluorescence and by lipid analysis of living cells. Our results suggested that the CGalT specifically uses hydroxyceramide for the synthesis of GalC and that separate (co)enzymes are not needed.