Selective enrichment of cDNAs from salt-stress-induced genes in the wheatgrass, Lophopyrum elongatum, by the formamide-phenol emulsion reassociation technique

We present a novel technique for the enrichment of cDNA libraries to enhance the abundance of clones of differentially expressed genes. The technique is relatively simple, requires moderate quantities of poly(A) + RNA and results in preferential enrichment of clones derived from mRNAs that were of low abundance in their original population. This method was used to isolate cDNA clones of salt-stress-induced genes in the roots of Lophopyrum elongatum, a highly salt-tolerant wheatgrass. An excess of sonicated plasmid DNA from a cDNA library from nonstressed roots was hybridized in a formamide-phenol emulsion with inserts from a cDNA library of stressed roots. Clones that were more abundant in, or were unique to, the library of the stressed roots were recovered as double-stranded fragments by virtue of reconstituted restriction-enzyme-digested ends by ligating them to a plasmid vector. The resulting enriched library was screened by differential colony hybridization and clones of eleven different genes that were more strongly expressed in stressed roots than in controls were selected.     

Cloning and Differential Expression of Two Catalases in Suaeda salsa in Response to Salt Stress

Two different cDNA clones (Sscat1 and Sscat2) encoding catalase, the primary important H2O2_scavenging enzyme, were isolated from a λZap_cDNA library constructed from a 400 mmol/L NaCl_treated library of Suaeda salsa (L.) Pall aerial tissue. Sscat1 (1.7 kb) contains a full open reading frame of 492 amino acids and Sscat2 (1.1 kb) is a partial clone. BLAST analysis indicates that the two clones share 71.9% identity in nucleotide sequence and 75% identity in deduced amino acid sequence within the last 287 amino acid residues of Sscat1. Southern blotting analysis showed that Sscat1 is multicopy in S. salsa genome, while Sscat2 is a single copy gene. Northern blotting analysis showed a rapid increase in the steady_level of both genes in roots after 48 h salt treatment, but only Sscat1 was induced in salinity treated leaves. Time_course analysis carried out in leaves confirmed that Sscat1 was induced by salt stress, in contrast to Sscat2. These implied that the expression of Sscat1 and Sscat2 genes are differentially regulated in S. salsa. The activity of total catalase is dramatically increased in response to salt stress.     

A combined molecular and cytogenetic approach to genome evolution in Drosophila using large-fragment DNA cloning

Methods of genome analysis, including the cloning and manipulation of large fragments of DNA, have opened new strategies for uniting molecular evolutionary genetics with chromosome evolution. We have begun the development of a physical map of the genome of Drosophila virilis based on large DNA fragments cloned in bacteriophage P1. A library of 10,080 P1 clones with average insert sizes of 65.8 kb, containing approximately 3.7 copies of the haploid genome of D. virilis, has been constructed and characterized. Approximately 75% of the clones have inserts exceeding 50 kb, and approximately 25% have inserts exceeding 80 kb. A sample of 186 randomly selected clones was mapped by in situ hybridization with the salivary gland chromosomes. A method for identifying D. virilis clones containing homologs of D. melanogaster genes has also been developed using hybridization with specific probes obtained from D. melanogaster by means of the polymerase chain reaction. This method proved successful for nine of ten genes and resulted in the recovery of 14 clones. The hybridization patterns of a sample of P1 clones containing repetitive DNA were also determined. A significant fraction of these clones hybridizes to multiple euchromatic sites but not to the chromocenter, which is a pattern of hybridization that is very rare among clones derived from D. melanogaster. The materials and methods described will make it possible to carry out a direct study of molecular evolution at the level of chromosome structure and organization as well as at the level of individual genes.     

Drosophila genome project: One-hit coverage in yeast artificial chromosomes

We present a strategy for assembling a physical map of the genome of Drosophila melanogaster based on yeast artificial chromosomes (YACs). In this paper we report 500 YACs containing inserts of Drosophila DNA averaging 200 kb that have been assigned positions on the physical map by means of in situ hybridization with salivary gland chromosomes. The cloned DNA fragments have randomly sheared ends (DY clones) or ends generated by partial digestion with either NotI (N clones) or EcoRI (E clones). Relative to the euchromatic portion of the genome, the size distribution and genomic positions of the clones reveal no significant bias in the completeness or randomness of genome coverage. The 500 mapped euchromatic clones contain an aggregate of approximately 100 million base pairs of DNA, which is approximately one genome equivalent of Drosophila euchromatin.by W. Hennig     

Digital mapping of bacterial artificial chromosomes by fluorescence in situ hybridization

The bacterial artificial chromosome (BAC) has become the most popular tool for cloning large DNA fragments. The inserts of most BAC clones average 100-200 kilobases (kb) and molecular characterization of such large DNA fragments is a major challenge. Here we report a simple and expedient technique for physical mapping of BAC inserts. Individual BAC molecules were immobilized on glass slides coated with Poly-L-lysine. The intact circular BAC molecules were visualized by fluorescence in situ hybridization using BAC DNA as a probe. The 7.4 kb BAC vector was extended to approximately 2.44 kb per micrometer. Digitally measured linear distances can be transformed into kilobases of DNA using the extension of BAC vector as a standard calibration. We mapped DNA fragments as small as 2 kb directly on circular BAC molecules. A rice BAC clone containing both tandem and dispersed repeats was analyzed using this technique. The distribution and organization of the different repeats within the BAC insert were efficiently determined. The results showed that this technique will be especially valuable for characterizing BAC clones that contain complex repetitive DNA sequences.     

Genetic and physical maps and a clone bank of mitochondrial DNA from rice

Summary Mitochondrial DNA (mtDNA) was isolated from young green leaves of rice plants. DNA fragments were cloned into lambda DNA, and clones that hybridized to mitochondrial genes from other plants were selected. Distal restriction fragments of these clones were used as probes for the selection of overlapping clones. A genetic map was finally created from the library by walking along the genome. The mitochondrial genome consists of five basic circles, with each circle sharing homologous sequences with one or two other circles. A master circle was constructed from the results of recombination across repeated sequences, and its size was estimated to be 492 kb. A physical map and a bank of overlapping clones were also constructed.     

Construction and Characterization of Two Bacterial Artificial Chromosome Libraries of Grass Carp

Bacterial artificial chromosome (BAC) library is an important tool in genomic research. We constructed two libraries from the genomic DNA of grass carp (Ctenopharyngodon idellus) as a crucial part of the grass carp genome project. The libraries were constructed in the EcoRI and HindIII sites of the vector CopyControl pCC1BAC. The EcoRI library comprised 53,000 positive clones, and approximately 99.94% of the clones contained grass carp nuclear DNA inserts (average size, 139.7 kb) covering 7.4× haploid genome equivalents and 2% empty clones. Similarly, the HindIII library comprised 52,216 clones with approximately 99.82% probability of finding any genomic fragments containing single-copy genes; the average insert size was 121.5 kb with 2.8% insert-empty clones, thus providing genome coverage of 6.3× haploid genome equivalents of grass carp. We selected gene-specific probes for screening the target gene clones in the HindIII library. In all, we obtained 31 positive clones, which were identified for every gene, with an average of 6.2 BAC clones per gene probe. Thus, we succeeded in constructing the desired BAC libraries, which should provide an important foundation for future physical mapping and whole-genome sequencing in grass carp.     

Patching broken chromosomes with extranuclear cellular DNA

Chromosomal double-strand breaks (DSBs) can be repaired by either homology-dependent or homology-independent pathways. Using a novel intron-based genetic assay to identify rare homology-independent DNA rearrangements associated with repair of a chromosomal DSB in S. cerevisiae, we observed that approximately 20% of rearrangements involved endogenous DNA insertions at the break site. We have analyzed 37 inserts and find they fall into two distinct classes: Ty1 cDNA intermediates varying in length from 140 bp to 3.4 kb and short mitochondrial DNA fragments ranging in size from 33 bp to 219 bp. Several inserts consist of multiple noncontiguous mitochondrial DNA segments. These results demonstrate an ongoing mechanism for genome evolution through acquisition of organellar and mobile DNAs at DSB sites.     

Construction of a Bacterial Artificial Chromosome Library of Phytophthora infestans and Transformation of Clones into P. infestans

A bacterial artificial chromosome (BAC) library of Phytophthora infestans was constructed in a derivative of pBELOBACII that had been modified by adding a npt selectable marker gene for transforming P. infestans. A total library of 8 genome equivalents was generated and 16,128 clones with inserts averaging 75 kb (4.9 genome equivalents) were individually picked and stored as an arrayed library in microtiter plates. This coverage was confirmed by screening the library for 11 DNA loci by colony hybridization and by polymerase chain reaction of DNA pools. Transformation of P. infestans with BAC clones containing inserts of 93 to 135 kb was demonstrated. The efficiency of transformation with most BACs was noticeably higher than that with smaller plasmids. Detailed analyses of transformants obtained with a 102-kb BAC indicated that entire inserts were present in about one-quarter of the transformants.     

Genetic heterogeneity of steroid sulfatase deficiency revealed with cDNA for human steroid sulfatase

Three cDNA clones with inserts of 1.2-1.6 kb that reacted both with antibodies and oligonucleotides specific for steroid sulfatase were isolated from a human placental library in lambda gt11. The 5'-end of one of the inserts, STS-3, was sequenced and colinearity with the amino acid sequence of 3 peptides of steroid sulfatase encompassing 64 amino acids was demonstrated. STS-3 hybridized with 2.5, 4.6 and 6.3 kb species in poly(A)+RNA and with 2.5, 4 and 9 kb fragments of EcoRI digested human DNA. The frequency of the EcoRI fragments in DNA from females was approximately twice that in DNA from males. DNA from two patients with steroid sulfatase deficiency and X-linked ichthyosis did not hybridize with STS-3. DNA from a third patient showed a normal hybridization pattern. It is concluded that steroid sulfatase deficiency is a genetically heterogenous disorder.