Pulsed field gradient electrophoresis of DNA digested in agarose allows the sizing of the large duplication unit of a surface antigen gene in trypanosomes

Characterization of the filarial genome

Filarial parasites are just beginning to be studied at the genetic level. The potential of recombinant DNA technology for identifying parasite genes that are important in the pathogenesis of filarial disease or for the survival of the parasite is enormous. Work in several laboratories has already identified genes which encode ribosomal RNAs, as well as highly repeated DNA sequences that can be used as diagnostic probes. In addition, new methods to separate chromosomes will allow the physical mapping of parasite genes without the requirement for classical genetic analysis, which would be difficult in filariids.

Simple screening method for differentially methylated regions of the genome using a small number of cells

Genomic DNA methylation is a major epigenetic mechanism controlling the expression of genetic information. Therefore, identifying regions of the genome that are differentially methylated in different cells is a useful strategy for the study of biological phenomena. To date, several useful screening methods have been established for identifying differentially methylated genomic regions. However, it is impossible to use these methods in fields of study in which it is difficult to obtain a large number of uniform cells, because considerable amounts of genomic DNA are required. Given this situation, we developed a method for preparing large genomic DNA from a small number of cells, and a simple and highly sensitive method for screening for differentially methylated sites. Combined, these two methods comprise a simple screening method, which we named "Differential Methylation Site Scanning" (DMSS), for identifying differentially methylated regions of the genome from a small number of cells. Just 10 cells are sufficient for the method described here.

Transfection of Actinomyces spp. by genomic DNA of bacteriophages from human dental plaque

Bacteriophages that produced turbid or clear zones of lysis in strains of Actinomyces were isolated from 22 of 124 samples of fresh human dental plaque. All human and nonhuman strains of Actinomyces viscosus or Actinomyces naeslundii tested in this study were sensitive to infection by one or more of these phages. In contrast, none of the Actinomyces odontolyticus, Actinomyces israelii, or Actinomyces bovis strains tested were susceptible. Results of restriction endonuclease analyses indicated that the genomes of these phages consisted of double-stranded DNA molecules ranging in size between 16 and 60 kbp. Sequence homology under hybridization conditions of high stringency was observed among a few of the isolated phages. A lysogenized isolate of A. viscosus MG-1 was obtained following infection with a temperate phage, designated phi 225. Results of Southern blot analyses indicated that phi 225 replicated as a plasmid in the lysogenized strain. Genomic DNA from several lytic phages was used to establish conditions for transfection by electroporation of strains of Actinomyces spp. Efficiencies of DNA transfer ranged from 10(2) to 10(5) plaque-forming units per microgram of DNA were obtained under optimal transfection conditions. The results of these studies demonstrate that transfer of genetic information in Actinomyces spp. can be achieved by transfection.

Comparison of properties of agarose for electrophoresis of DNA

Agarose as a medium for separation of DNA was first introduced in 1962 and since the early 1970s agarose submarine gel electrophoresis has been synonymous with separations of DNA molecules larger than 1 kilobase pair (kb). The large pore size, low electroendosmosis and strength of the matrix have advantages over other media such as polyacrylamide for many applications. The variety of grades of agarose, developed by chemical manipulation of the substitutions on the agarose polymer, provides a range of matrices for separation of DNA molecules from a few base pairs (bp) to over 5 megabase pairs (Mb) in length. The introduction of low-melting-temperature agarose has revolutionised the extraction and manipulation of chromosome-sized molecules. On the other hand, the demand for analysis of very small quantities of DNA will most likely lead to the increasing importance of capillary electrophoresis. Many theories have been propounded to explain the electrophoretic migration of DNA in agarose. The most popular of these has been reptation theory but none can account for all of the reported anomalies in migration. However, anomalous migration has been exploited to study DNA structure, topology and catenation. An example of the use of two-dimensional electrophoresis to demonstrate the complexity of DNA migration through agarose is given. Generally, for molecules smaller than 50 kb, electrophoretic separation is a function of length. By alternately electrophoresing DNA in two different directions, molecules as large as 5.7 Mb have been effectively separated, although with such large molecules DNA structure as well as size may determine migration. In the case of separations of chromosomes from the intestinal protozoan, Giardia duodenalis, for example, a discrepancy of 1 Mb in the size of one chromosome, with an apparent size of 0.7-2.0 Mb, depended on the boundary conditions of separation. Major challenges for the molecular biologist are separation of larger chromosomal sized molecules, greater number of samples and smaller formats. Towards this challenge computer-aided technology is a key component in the control of electrophoresis parameters and analysis.

Field alternation gel electrophoresis--status quo

Since the description of the original technique of field alternation gel electrophoresis (FAGE) about ten years ago there have been significant developments in the area. Between 1983 and early 1987 dramatic improvements in the technique and apparatus resulted in a 500- to 600-fold increase in the functional separation capacity of conventional agarose gel electrophoresis. Details of the improvements in technique and equipment was the subject of an earlier review [H. J. S. Dawkins, J. Chromatogr., 492 (1989) 615]. This review concentrates on the application of FAGE technology. The FAGE technique is no longer restricted to simply separating large DNA fragments. This method is presently being used for electrophoretic karyotyping, long-range genomic mapping, cloning of large DNA fragments into new vectors, the study of pathogenic chromosomal alterations and the structural analysis of chromosomes. The applications of FAGE in molecular biology and genetics is constantly expanding, with the full potential of this technique still to be realised.

Estimation of ruminal bacteriophage numbers by pulsed-field gel electrophoresis and laser densitometry

To investigate phage activity in the rumen, a method for quantifying phage has been developed. By differential centrifugation and ultrafiltration, phage particles were separated and concentrated from ruminal fluid. Linear double-stranded DNA from this fraction containing predominantly tailed phage was isolated and separated by size, using pulsed-field gel electrophoresis (PFGE). Laser densitometry of gel photographs allowed the numbers of phages with DNA in each size region to be calculated and, therefore, the total numbers per milliliter of ruminal fluid to be estimated. Phage numbers were estimated to be between 3 x 10(9) and 1.6 x 10(10) particles ml of ruminal fluid-1. The phage population, as gauged by the appearance of DNA on PFGE gels, had two major components. A broad region of DNA between 30 and 200 kb was always present on PFGE gels. It appears this region comprises DNA from a great many different phages and would include most of the temperate phages. In addition, discrete DNA bands ranging in size from 10 to 850 kb were frequently observed. DNA from one such band, of 12 kb in size, was shown to consist primarily of a single DNA type, suggesting that it originated from a specific phage. It is postulated that the discrete bands are due to epidemics or blooms of phage activity from specific, probably lytic, phages. The method that has been developed will greatly enhance future investigations into the interactions between the ruminal phage population, the ruminal bacterial population, and animal nutrition and growth.(ABSTRACT TRUNCATED AT 250 WORDS)

A new member of a family of site-specific retrotransposons is present in the spliced leader RNA genes of Trypanosoma cruzi

A new member of a family of site-specific retrotransposons is described in the New World trypanosome Trypanosoma cruzi. This element, CZAR (cruzi-associated retrotransposon), resembles two previously described retrotransposons found in the African trypanosome T. brucei gambiense and the mosquito trypanosomatid Crithidia fasciculata in specifically inserting between nucleotides 11 and 12 of the highly conserved 39-mer of the spliced leader RNA (SL-RNA) gene. CZAR is similar in overall organization to the other two SL-RNA-associated elements. It possesses two potential long open reading frames which resemble the gag and pol genes of retroviruses. In the pol open reading frame, all three elements contain similarly arranged endonuclease domains and share extensive amino acid homology in the reverse transcriptase region. All are associated with the SL-RNA gene locus and are present in low copy numbers. They do not appear to have 5' truncated versions. All three retrotransposons are otherwise quite distinct from one another, with no significant overall amino acid homology. The presence of such retroelements inserted into the identical site within SL-RNA gene sequences in at least three evolutionarily distant trypanosomatid species argues for a functional role. Because these elements appear to have a precise target site requirement for integration, we refer to them as SL siteposons.

A new member of a family of site-specific retrotransposons is present in the spliced leader RNA genes of Trypanosoma cruzi

A new member of a family of site-specific retrotransposons is described in the New World trypanosome Trypanosoma cruzi. This element, CZAR (cruzi-associated retrotransposon), resembles two previously described retrotransposons found in the African trypanosome T. brucei gambiense and the mosquito trypanosomatid Crithidia fasciculata in specifically inserting between nucleotides 11 and 12 of the highly conserved 39-mer of the spliced leader RNA (SL-RNA) gene. CZAR is similar in overall organization to the other two SL-RNA-associated elements. It possesses two potential long open reading frames which resemble the gag and pol genes of retroviruses. In the pol open reading frame, all three elements contain similarly arranged endonuclease domains and share extensive amino acid homology in the reverse transcriptase region. All are associated with the SL-RNA gene locus and are present in low copy numbers. They do not appear to have 5' truncated versions. All three retrotransposons are otherwise quite distinct from one another, with no significant overall amino acid homology. The presence of such retroelements inserted into the identical site within SL-RNA gene sequences in at least three evolutionarily distant trypanosomatid species argues for a functional role. Because these elements appear to have a precise target site requirement for integration, we refer to them as SL siteposons.

Orientation of HLA-DNA gene and identification of a CpG island-associated gene adjacent to DNA in human major histocompatibility complex class II region

We have constructed the detailed physical map of the HLA class II gene region by the pulsed field gel electrophoresis (PFGE) and cosmid walking technique. In this process, the DNA gene was found to be located telomeric to DPA1 with the 5'----3' orientation which is the same as the DPA1 and DPA2 genes, but opposite to the DQA1, DQA2 and DRA genes. This orientation is reverse to that of the counterpart gene in the rabbit major histocompatibility complex region. About 30 kb downstream from the DNA gene towards DOB, a CpG island characterized by clustered sites for rare cutting restriction enzymes and frequently associated with the 5' end of housekeeping genes was identified by PFGE and cosmid walking. From a complementary DNA (cDNA) library constructed from a Epstein-Barr virus-transformed B-cell line, a cDNA clone was isolated using the genetic probe from this CpG island. Its nucleotide sequences suggested that it represented a new non-HLA gene with a single copy which was of little genetic polymorphism and named NAT (DNA-associated transcript). Northern blot analysis showed that the NAT gene was expressed with a 4-kb transcript in all of tissues examined so far.

An expression-site-associated gene family of trypanosomes is expressed in vivo and shows homology to a variant surface glycoprotein gene

Utilizing first-strand cDNA from different stages, a gene family was identified that is expressed in bloodstream form trypanosomes but not in cultured procyclic forms. This family of 50-100 genes, termed bloodstream-specific 1 (BS1), shares a chromosomal distribution pattern similar to the variant surface glycoprotein (VSG) genes and the expression-site-associated genes (ESAGs). The BS1 genes are expressed in several variants of Trypanosoma brucei brucei and in Trypanosoma brucei gambiense. Sequence analysis of five members of this gene family reveals the recently described ESAG 6 and ESAG 7 genes as well as the ESAG X gene to be members of this family. We have been unable to localize the BS1 gene product in the cell but show that chronically infected rabbit serum recognizes recombinant BS1 protein arguing for expression in vivo. Finally we note that the derived protein sequence for the BS1 genes suggests an evolutionary relationship with at least one variant surface glycoprotein gene, and hence these studies may provide clues to understanding the molecular origins of antigenic variation in trypanosomes.

Giardia sp.: comparison of electrophoretic karyotypes

Species in the genus Giardia have been named on the basis of host specificity, cell dimensions, and median body morphology. Despite these criteria, the species taxonomy of Giardia is still in question. To investigate Giardia taxonomy on a molecular level, Giardia chromosomal DNA was analyzed by orthogonal-field-alternation gel electrophoresis (OFAGE) and transverse alternating field electrophoresis (TAFE). Chromosomal DNA of G. duodenalis isolates (human, muskrat, sheep, dog, beaver), G. muris (mouse), and G. ardeae (great blue heron) were subjected to OFAGE and TAFE analyses. Comparable DNA patterns were obtained by both electrophoretic methods, but OFAGE required 8 days while TAFE required only 3 days. DNA patterns among all G. duodenalis isolates, although quite similar to each other, were distinctly different from those of G. muris and G. ardeae; G. muris and G. ardeae DNA patterns were distinctly different from each other. A G. duodenalis (Portland 1) total DNA probe hybridized to the DNA of all G. duodenalis isolates on Southern blots, but not detectably to G. muris and G. ardeae DNA. Similarly, G. muris and G. ardeae total DNA probes only hybridized detectably to their respective DNA. One probe that appears to hybridize to the DNA of all G. duodenalis and to G. ardeae DNA rather than G. muris DNA has been developed. Another probe that hybridizes only to G. muris and G. ardeae DNA has been developed. These data suggest that the differentiation of Giardia isolated from host and environmental samples may eventually be accomplished by DNA probes. Additionally, these techniques perhaps combined with other criteria may lead to the establishment of a sound taxonomic scheme for this genus.

Use of pulsed-field agarose gel electrophoresis to size genomes of Campylobacter species and to construct a SalI map of Campylobacter jejuni UA580

To determine the physical length of the chromosome of Campylobacter jejuni, the genome was subjected to digestion by a series of restriction endonucleases to produce a small number of large restriction fragments. These fragments were then separated by pulsed-field gel electrophoresis with the contour-clamped homogeneous electric field system. The DNA of C. jejuni, with its low G+C content, was found to have no restriction sites for enzymes NotI and SfiI, which cut a high-G+C regions. Most of the restriction enzymes that were used resulted in DNA fragments that were either too numerous or too small for genome size determination, with the exception of the enzymes SalI (5' ... G decreases TCGAG ... 3'), SmaI (5' .... CCC decreases GGG .... 3'), and KpnI (5' ... GGTAC decreases C .... 3'). With SalI, six restriction fragments with average values of 48.5, 80, 110, 220, 280, and 980 kilobases (kb) were obtained when calibrated with both a lambda DNA ladder and yeast Saccharomyces cerevisiae chromosome markers. The sum of these fragments yielded an average genome size of 1.718 megabases (Mb). With SmaI, nine restriction fragments with average values ranging from 39 to 371 kb, which yielded an average genome size of 1.726 Mb were obtained. With KpnI, 11 restriction fragments with sizes ranging from 35 to 387.5 kb, which yielded an average genome size of 1.717 Mb were obtained. A SalI restriction map was derived by partial digestion of the C. jejuni DNA. The genome sizes of C. laridis, C. coli, and C. fetus were also determined with the contour-clamped homogeneous electric field system by SalI, SmaI, and KpnI digestion. Average genome sizes were found to be 1.714 Mb for C. coli, 1.267 Mb for C. fetus subsp. fetus, and 1.451 Mb for C. laridis.

Pneumocystis carinii karyotypes

Pulsed-field gel electrophoresis techniques were used to examine the chromosomes of Pneumocystis carinii isolated from laboratory rats and two human subjects. P. carinii organisms isolated from each of four rat colonies and from two patients each produced a distinct band pattern, but in all cases the bands ranged in size from 300 to 700 kilobase pairs. P. carinii from three rat colonies produced patterns containing 15 prominent bands. Of these 15 bands, 2 stained more intensely than would be expected of bands of their size, suggesting that the P. carinii haploid genome contains 17 to 19 chromosomes. Summing the molecular sizes of the bands and accounting for staining intensities suggested that the haploid genome of rat-derived P. carinii contains on the order of 10(7) base pairs. Human-derived P. carinii produced patterns containing 10 to 12 bands which appeared to be similar to the 15-band patterns seen in rat-derived P. carinii with respect to the size range of the bands. P. carinii from the fourth rat colony produced a more complex band pattern containing approximately 22 bands, most of which appeared to comigrate with the bands present in one of the 15-band P. carinii patterns, suggesting that these animals were simultaneously infected by two different varieties of P. carinii. Hybridization experiments using oligonucleotide probes specific for the P. carinii 18S rRNA gene supported this possibility. The band pattern of P. carinii derived from a given rat colony was generally stable over time. P. carinii band patterns were not strictly rat strain specific and appeared to be transferrable between animals housed in the same room.

Physical mapping and field inversion gel electrophoresis of Amsacta moorei entomopoxvirus DNA

Agarose in situ digestion was used to prepare intact Amsacta moorei entomopoxvirus (AmEPV) DNA from embedded occlusion bodies (OBs). Direct dissolution of OBs in agarose eliminated the necessity for separate purification of virions. A physical map of AmEPV DNA was constructed for five restriction enzymes (BamHI, EcoRI, HindIII, PstI, and XhoI) using single and multiple digests, and isolated fragment digestions. End fragments were identified by Bal31 digestion and snap-back analysis. A least squares procedure was used to reconcile fragment lengths. AmEPV genome size estimates were based on restriction enzyme (REN) fragment length totals (222 kb), reconciled physical map distance (225 kb), and field inversion gel electrophoresis (FIGE) (about 242 kb). Presumably due to the high A + T content (18.5% G + C) of AmEPV DNA, FIGE values for the intact genome and large REN fragments were about 6 to 10% higher than expected. Preparative FIGE was used to concentrate AmEPV DNA from agarose microbead encapsulated insect cells (Estigmene acrea, BTI-EAA). REN digests of this DNA were identical to those from OBs from caterpillars.

Inhibition of replicon cluster ligation into chromosomal DNA at elevated temperatures

The rate-limiting enzymatic step for DNA replication in HeLa cells incubated at 43.5 degrees C was the ligation of clusters of replicons into the cell's genome. At 43.5 degrees C the reciprocal slope for inhibition of DNA chain (replicon) initiation, or of the ligation of replicon clusters into the genome, was 18 or 7 min, respectively. The failure of replicon clusters to be ligated into chromosomal DNA was not a consequence of the failure of histone proteins to be deposited onto replicating DNA, or of chromatin replicated at 43.5 degrees C to be organized into fully condensed chromatin. In addition it was not due to the failure of fully active topoisomerase II to be deposited at a normal frequency along replicating chromatin DNA. The failure of replicon clusters to be ligated into the genome resulted in the persistence of single, but not double, DNA strand breaks in the cell's genome 24 hours after cell heating.

Extensive homologies between Leishmania donovani chromosomes of markedly different size

The smallest chromosome (230 kb) of the HU3 stock of Leishmania donovani was purified from an orthogonal field alternation (OFAGE) gel, digested with PstI and cloned into the plasmid pUC13. When used to probe Southern blots of OFAGE gels, the cloned sequences recognised one or more large chromosomes in all L. donovani stocks and a small chromosome in HU3 and two additional L. donovani stocks (Khartoum and DD8). These probes recognised a single band on Southern blots of restricted genomic DNA regardless of their homologies to only large or large and small chromosomes. Analysis of lambda EMBL3 genomic clones selected with the same probes suggested that at least 30 kb of DNA was common to large and small chromosomes. Most of the cloned sequences were mapped to the same 50-kb SfiI fragment present in both chromosomes. These data indicate that two or more L. donovani chromosomes of markedly different size on OFAGE gels are extensively homologous.

Large DNA separation using field alternation agar gel electrophoresis

The techniques for large DNA separation have developed from a seminal idea for field alternation which has transformed the field of DNA electrophoresis. This single innovation of pulsed field-gradient electrophoresis (PFGE) and the subsequent modifications have made a significant impact on molecular biology, eukaryote genetics, biopolymer research and diagnostic research. The apparatus types used for large DNA separation are depicted and critically compared with relation to molecular mass separation capabilities, straight-lane migration of samples, band sharpness and ease of operation. With these criteria in mind PFGE and orthogonal field alternation gel electrophoresis systems had a number of drawbacks, the principle one being the inability of these systems to give straight-lane migration. To a large extent this has restricted the widespread use of these systems. Field inversion gel electrophoresis produces straight-lane migration but was subject to an upper molecular mass limitation of 2 megabase pairs and tended to produce broader bands in the higher-molecular-mass areas. Transverse alternating field electrophoresis, rotating gel electrophoresis and contour-clamped homogeneous electric field electrophoresis systems where superior to all the other systems. They gave straight-lane migration, separation of chromosomes up to 10 megabase pairs, good resolution of bands and were all relatively simple to operate. Very little was found to separate these three electrophoresis systems. Field alternation electrophoresis has enabled a 500-fold increase in the size of DNA molecules that can be resolved in agar gels. Consequently, electrophoretic karyotypes of a number of organisms have been produced, while genome maps, gene locations and sequences of large areas of mammalian genomes are now being undertaken. The ability to separate entire chromosomes or large DNA fragments has, in conjunction with novel molecular biology techniques, enabled scientists to work backwards from large purified fragments or entire chromosomes to construct long-range genetic maps. The time saving alone when compared with the old techniques of using very small fragments to construct a picture of the gene or gene complex is commendable. The diagnostic role of large DNA separation and electrophoretic karyotyping is beginning to be explored, while the use of this technique for clinical studies of genetic disorders is well advanced. Very few innovations in nucleic acid separation have had as marked an influence on as many areas as field alternation electrophoresis. These techniques have brought mapping of the mammalian genome into the realms of possibility and is contributing in many sphere

The karyotype of Trypanosoma cruzi Dm 28c: comparison with other T. cruzi strains and trypanosomatids

Chromosome-sized DNA molecules from Trypanosoma cruzi clone Dm 28c were analyzed and compared with other T. cruzi strains and monogenetic trypanosomatids by orthogonal field alteration gel electrophoresis. The results showed that T. cruzi Dm 28c displays at least 18 chromosomes ranging from 550 to more than 1500 kb and that in general the trypanosomatids have smaller chromosomes distributed in the size range from 300 to 1500 kb. With the exception of T. cruzi strain G49, there is no evidence of minichromosomes, suggesting they are not widely distributed among different isolates of the parasite. The hybridization of T. cruzi chromosomal Southern blots with probes for T. cruzi-specific genes showed that their location can change from one strain to another, supporting the idea of the plasticity of the parasite genome. Furthermore, the chromosome pattern is strictly conserved during the transformation of T. cruzi Dm 28c epimastigotes to metacyclic trypomastigotes, suggesting that extensive chromosomal rearrangements do not occur during at least part of the life cycle of the parasite.

Geographic variation in Giardia karyotypes

Chromosomes of 41 stocks of Giardia duodenalis derived from humans and 14 stocks from other animal species were analysed by field inversion gel electrophoresis (FIGE). These stocks have two predominant karyotypes as judged by FIGE which appear to fit a geographic distribution. Under FIGE conditions used to optimize the detection of size variation in Giardia chromosomes, five or six major chromosomes could be identified. Most of the stocks derived from North America have three major chromosomes smaller than 800 kb while most of the Australian stocks have four. A few exceptions, and minor variations, of these karyotypes were observed. It was estimated that not all of the DNA entered the gel, the remainder being trapped conformations or very large chromosomes. Karyotypes of Giardia stocks from different animal hosts and human sources within a geographical region are similar.

A physical map around the WAGR complex on the short arm of chromosome 11

A long-range restriction map of part of the short arm of chromosome 11 including the WAGR region has been constructed using pulsed-field gel electrophoresis and a number of infrequently cutting restriction enzymes. A total of 15.4 Mbp has been mapped in detail, extending from proximal 11p14 to the distal part of 11p12. The map localizes 35 different DNA probes and reveals at least nine areas with features characteristic of HTF islands, some of which may be candidates for the different loci underlying the phenotype of the WAGR syndrome. This map will furthermore allow screening of DNA from individuals with WAGR-related phenotypes and from Wilms tumors for associated chromosomal rearrangements.

DNA electrophoresis

The migration of a series of supercoiled plasmids ranging in size from 4 to 91 kilobases (kb) has been analyzed by orthogonal-field-alternation gel electrophoresis (OFAGE). These circular DNAs enter OFAGE gels and are resolved over the same region of the gel as linear DNAs from 260 to 2200 kb. Furthermore, a distinct triphasic migration pattern was observed for the supercoiled DNAs. The migration of plasmids between 6 and 20, and 60 and 91 kb is inversely proportional to size, whereas the mobilities of plasmids between 20 and 60 kb increase with size. Unlike linear DNA molecules, the relative mobilities of these plasmids are constant over a broad range of pulse times, from 10 to 120s. Electrophoresis of supercoiled, relaxed, and nicked open circular forms as well as topoisomers of small plasmids shows that the extent of supercoiling has a dramatic effect on plasmid migration on OFAGE. Several practical applications for exploiting the different migration properties of circular and linear DNA molecules on OFAGE are presented.

Direct observation of the gene organization of the complement C4 and 21-hydroxylase loci by pulsed field gel electrophoresis

Pulsed field gel electrophoresis and enzymes that cut genomic DNA infrequently have been used to define large RFLPs at the human C4 loci. With the enzymes BssH II or Sac II, and C4 or 21-hydroxylase DNA probes, it has been possible to observe directly the number of C4 genes present on a haplotype, and also whether the C4 genes are long (6-7-kb intron present) or short (6-7-kb intron absent). Haplotypes that have either two long C4 genes or one long and one short C4 gene generate BssH II fragments of approximately 115 or approximately 105 kb, respectively. Haplotypes that have either a single long or a single short C4 gene generate BssH II fragments of approximately 80 or approximately 70 kb, respectively. This technique has been used to analyze the DNA isolated from PBMC and allows the complete definition of the C4 gene organization of an individual without the need for family studies.

Improved separation of chromosome-sized DNA from Trypanosoma brucei, stock 427-60

Separation of chromosome-sized DNA from the parasitic protozoan Trypanosoma brucei had previously resulted in the fractionation of DNA molecules that ranged in size from 50 kb up to roughly 1.5 Mb. The number of larger chromosomes and their size, accounting for 80% of the DNA of T. brucei remained unclear. We have now size separated these larger DNA molecules by pulsed field gel electrophoresis (PFG) and resolve a total of 20 bands, accounting for roughly 120 chromosomes, ranging in size from 50 kb up to the size of the largest, 5.7 Mb chromosome of Schizosaccharomyces pombe. Three different VSG gene expression sites were located to chromosomes of 430 kb, 1.5 Mb and 3 Mb, respectively. We have not been able to identify additional, previously cryptic DNA rearrangements, that could explain the activation or inactivation of the expression sites.

Preparation of plant DNA for separation by pulsed field gel electrophoresis

A method was developed for the preparation of completely intact plant DNA embedded in agarose, and suitable for restriction enzyme digestion. Digestion with restriction enzyme was carried out according to modified protocols of Anand and Kenwrick et al. The new method of DNA isolation allows the separation of high molecular weight plant DNA by pulsed field gel electrophoresis.

The first BCR gene intron contains breakpoints in Philadelphia chromosome positive leukemia

The hallmark of chronic myelogenous leukemia (CML) is a translocation between chromosomes 9 and 22 - the Philadelphia (Ph') translocation. The translocation is also found in acute lymphocytic leukemia (ALL) albeit in a lower percentage of patients. The breakpoint on chromosome 22 is located within the BCR gene: in CML, breakpoints are clustered within 5.8 kb of DNA, the major breakpoint cluster region (Mbcr). In ALL, breakpoints have been reported within the Mbcr but also in more 5' regions encompassing the BCR gene. To characterize the latter breakpoints, we have molecularly cloned and mapped the entire gene, which encompasses approximately 130 kb of DNA. Mbcr negative, Ph'-positive ALL breakpoints were not distributed at random within the gene but rather were found exclusively within the 3' half of the first BCR gene intron. In contrast to the Mbcr, which is limited to a region of 5.8 kb, this part of the intron has a size of 35 kb. Translocation breakpoints in this region appear to be specific for ALL, since it was not rearranged in clinically well-defined CML specimens nor in any other tumor DNA samples examined.

Boundaries of telomere conversion in Trypanosoma brucei

Active genes for variant-specific surface glycoproteins (VSGs) reside in telomeric expression sites and may be replaced by other VSG genes via telomere conversions. The availability of a complete map of expression site 221 in variant 221a made it possible to determine the boundaries of such conversions and the sequences that are involved. We have analysed five trypanosome populations that arose from variant 221a through replacement of the 221 gene by another VSG gene. In each of these relapsed populations the telomere conversion ends at a different position in the expression site. In the relapsed population, 221aR3, the boundary was found in the coding region of an expression-site-associated gene (ESAG). This ESAG-2 codes for a potential 368-aa protein of unknown function; it contains a N-terminal signal peptide for mediating transfer to the endoplasmic reticulum and six potential N-glycosylation sites. It shares these structural features with the ESAG-1 protein encoded in the same expression site. ESAG-2 is a member of a large gene family which includes non-functional genes. In 221aR3, the partial conversion of ESAG-2 by an ESAG-2-like sequence has disrupted the open reading frame. The two ESAG-2 sequences are similar (92% identity) suggesting that sequence homology between telomeres provides the opportunity for gene conversion.

Insertion of transformation vector DNA into different chromosomal sites of Dictyostelium discoideum as determined by pulse field electrophoresis

Chromosomes of the cellular slime mold Dictyostelium discoideum were fractionated on three pulse field gel electrophoresis systems (pulse field, orthogonal field and C.H.E.F. (Contour-clamped Homogeneous Electric Fields] into a series of 13 bands ranging from 0.1 Mb to over 2 Mb in size. Since this organism has only seven chromosomes (estimated to be 1-10 Mb), and -90 copies of an 88-kilobase linear ribosomal DNA molecule (14% of genome), it was apparent that not all of these bands were whole chromosomes. However these bands were reproducibly obtained with the cell preparation used. They fell into three categories: i) four large poorly resolved DNA molecules (-2 Mb in size) which represent very large fragments or intact chromosomes, ii) eight faint bands ranging from 0.1 Mb to 2 Mb, iii) a prominent band in the apparent size range of about 0.15 Mb. Cloned Fragment V of an EcoR1 digest of the ribosomal DNA, hybridized to the 0.15 Mb band indicating it contained the linear ribosomal DNA. This chromosomal banding pattern was used to examine the stability and location of vector DNA in 16 transformed strains of D. discoideum. Each transformed strain was initially selected on the basis of G418 resistance with an integrating vector containing pBR322 sequences. Eleven transformants still carried pBR322 sequences after more than 60 generations of growth without selection on G418. All four strains transformed with constructs containing regions of the D. discoideum plasmid Ddp1 had lost their pBR322 insert, indicating that integration of Dictyostelium plasmid DNA into chromosomes leads to instability. Orthogonal field electrophoresis of the eleven strains still carrying pBR322 sequences revealed at least seven different integrating sites for the transforming DNA. We conclude that these vectors have many possible sites of integration in the D. discoideum genome.

Circular DNA of 3T6R50 double minute chromosomes

In pulsed field gradient gel electrophoresis (PFGE) the intact deproteinized circular DNA of Mycoplasma (800 kb) and Escherichia coli (4700 kb) remains trapped in the slot. We show here that gamma-irradiation of the DNA in agarose plugs is a convenient method to partially convert these circles into full-length linears, migrating with the expected mobility in PFGE. We have used this method to study the structure of Double Minute chromosomes (DMs) from the methotrexate (MTX)-resistant mouse cell line 3T6R50. Intact deproteinized DM DNA is immobile in these gels, but is converted into a single band of about 2500 kb by either gamma-irradiation, DNaseI in the presence of Mn2+, or restriction enzymes. We conclude that the DM DNA in 3T6R50 cells consists of a homogeneous population of 2500-kb circles.

A 10-megabase physical map of human Xp21, including the Duchenne muscular dystrophy gene

Using pulsed-field gel electrophoresis and 12 Xp21-derived DNA probes, we have constructed a continuous restriction map spanning more than 4 million base pairs (4 Mbp), including the Duchenne muscular dystrophy gene of more than 2 Mbp. This detailed map is part of a less detailed map spanning 10 Mbp, also spanning the genes for glycerol kinase and congenital adrenal hypoplasia, constructed under electrophoresis conditions which separated DNA fragments in the range 200 to 4000 kbp. DNA from three different tissues was analyzed, and differential methylation was observed.

Plasmodium falciparum: mapping genes to nine parasite chromosomes

Using pulsed field gel electrophoresis with pulse time of 120 sec, eight chromosomal DNA molecules from clone 7G8 of the Plasmodium falciparum Brazilian isolate IMTM22 were resolved. A ninth chromosomal molecule which did not enter the gel was identified at the slot by hybridization to two DNA probes and by restriction enzyme analysis. Thirteen parasite DNA sequences were mapped to the nine chromosomes, with at least one sequence mapped to each chromosome. The restriction enzyme NotI appeared to produce only one cut in the entire IMTM22 genome.

The first intron in the human c-abl gene is at least 200 kilobases long and is a target for translocations in chronic myelogenous leukemia

The c-abl protooncogene is unusual in two respects; it has multiple, widely space N-terminal coding exons transcribed by different promoters, and it is the target of the translocations that form the Philadelphia chromosome found in cells of chronic myelogenous leukemia patients. To understand the organization of the gene in normal and chronic myelogenous leukemia patient DNA we have mapped c-abl by pulsed field gradient gel electrophoresis. We find that one of the alternative 5' exons of the gene lies at least 200 kilobases upstream of the remaining c-abl exons, posing formidable transcription and splicing problems. The 5'-most c-abl exon includes an unusually long 1,276-base-pair segment that contains 15 ATG codons and multiple short open reading frames, upstream of the abl initiator codon. Its peculiar structure suggests that c-abl may be decapitated in most chronic myelogenous leukemia patients, and we demonstrate that this is the case in the chronic myelogenous leukemia cell line K562.

Linkage of TNF genes to the HLA-B locus

Pulsed field gel electrophoresis was used to determine the location of the tumour necrosis factor (TNF) alpha and beta genes. They were shown to be linked to the HLA-B locus; analogous to their location in mouse, between the complement (class III) region and H-2D. However, the distance between the TNF genes and the class I region was much greater in man, namely about 260 kb, compared to 70 kb in the mouse. This finding may have implications for some HLA associated diseases.

Organization of the T-cell antigen-receptor beta-chain locus in mice

We used pulsed-field gel electrophoresis to determine the organization of the beta-chain gene of the T-cell receptor for antigen in normal and mutant inbred strains of mice. In normal mice, the variable (V)- and constant (C)- region elements of this locus span 700-800 kilobases of chromosomal DNA. All but one of the V beta gene segments analyzed lie 5' of the J beta C beta locus (J beta represents the joining region), with the closest being 280-360 kilobases away. The mutant mouse strain SJL has an internal V beta-region gene deletion that compacts the V beta region by 100-200 kilobases. Taken together with other data, these results indicate that the beta-chain locus can use either a looping-out/deletion or an inversion mechanism to appose V beta to DJ beta gene segments (D is the diversity region) and can accomplish the former (at least) over very large distances.

Pulsed-field electrophoresis: application of a computer model to the separation of large DNA molecules

The biased reptation theory has been applied to the pulsed-field electrophoresis of DNA in agarose gels. A computer simulation of the theoretical model that calculates the mobility of large DNA molecules as a function of agarose pore size, DNA chain properties, and electric field conditions has been used to generate mobility curves for DNA molecules in the size range of the larger yeast chromosomes. Pulsed-field electrophoresis experiments resulting in the establishment of an electrophoretic karyotype for yeast, where the mobility of the DNA fragments is a monotonic function of molecular size for the entire size range that is resolved (200-2200 kilobase pairs), has been compared to the theoretical mobility curves generated by the computer model. The various physical mechanisms and experimental conditions responsible for band inversion and improved electrophoretic separation are identified and discussed in the framework of the model.

Plasmid migration using orthogonal-field-alternation gel electrophoresis

The migration properties of a series of supercoiled plasmids ranging in size from 4 to 16 kilobases (kb) have been analyzed by orthogonal-field-alternation gel electrophoresis (OFAGE). These circular DNAs enter the gel and are well resolved. Unlike linear DNA molecules, the relative mobilities of these plasmids are constant over a wide range of pulse times, from 10 to 120 seconds, as well as over a broad range of total running times, from 6 to 24 hours. Electrophoresis of supercoiled, relaxed, and nicked open circular forms as well as topoisomers of pBR322 shows that the extent of supercoiling has a dramatic effect on plasmid migration on OFAGE. Several practical applications for exploiting the different migration properties of circular and linear DNA molecules on OFAGE are presented.

The anatomy and transcription of a telomeric expression site for variant-specific surface antigens in T. brucei

The variant specific surface glycoprotein (VSG) genes of T. brucei are expressed in telomeric expression sites. We have determined the structure of the active site in trypanosome variant 221a, which contains VSG gene 221, by analysis of cloned DNA segments that represent 65 kb of the 5'-flanking region of the VSG gene. In nuclear run-on experiments, 57 kb of adjacent sequences are cotranscribed with the VSG gene at approximately similar rates and in the alpha-amanitin-resistant manner characteristic of VSG genes. Besides the VSG mRNA, this expression site yields at least seven stable RNAs, suggesting that it is a multicistronic transcription unit. Our results also show that insertion of a transcriptional terminator is not the general mechanism of switching off expression sites.

Resolution of DNA molecules greater than 5 megabases by contour-clamped homogeneous electric fields

Excellent resolution of chromosomal DNA molecules from Saccharomyces cerevisiae, Candida albicans and Schizosaccharomyces pombe has been obtained using alternating contour-clamped homogeneous electric field (CHEF) gel electrophoresis. The largest of these molecules is greater than 5 Mb in size and is resolved after 130 hours in a 0.6% agarose gel at a field strength of 1.3 V/cm and a switching interval of 1 hour. Separation of concatamers of phage lambda DNA reveals four regions of resolution in alternating CHEF gel electrophoresis. There are two regions of good resolution in which mobility approximates a linear function of molecular weight. These are separated by a region of lower resolution and bounded at high molecular weights by a region of little or no resolution. The four regions are of practical and possibly theoretical importance.

The first intron in the human c-abl gene is at least 200 kilobases long and is a target for translocations in chronic myelogenous leukemia

The c-abl protooncogene is unusual in two respects; it has multiple, widely space N-terminal coding exons transcribed by different promoters, and it is the target of the translocations that form the Philadelphia chromosome found in cells of chronic myelogenous leukemia patients. To understand the organization of the gene in normal and chronic myelogenous leukemia patient DNA we have mapped c-abl by pulsed field gradient gel electrophoresis. We find that one of the alternative 5' exons of the gene lies at least 200 kilobases upstream of the remaining c-abl exons, posing formidable transcription and splicing problems. The 5'-most c-abl exon includes an unusually long 1,276-base-pair segment that contains 15 ATG codons and multiple short open reading frames, upstream of the abl initiator codon. Its peculiar structure suggests that c-abl may be decapitated in most chronic myelogenous leukemia patients, and we demonstrate that this is the case in the chronic myelogenous leukemia cell line K562.

Transient rearrangements of the T cell antigen receptor alpha locus in early thymocytes

The dull Ly-1 double-negative (Ly-1dull, Lyt-2-, L3T4-) subpopulation appears to be the major precursor group of T lymphocytes in the thymus. In examining the status of the alpha, beta, and gamma chain genes for T cell receptors (TCR) in this population of cells and hybridomas made from them, we find that all of these loci appear to begin DNA rearrangements in a nearly simultaneous fashion. In the case of the gamma genes, these involve V gamma----J gamma C gamma gene rearrangements; with the beta chain genes, both D beta----J beta C beta rearrangement and V beta----D beta J beta C beta rearrangements are evident; and in the case of the alpha locus, assayed in part by pulsed-field gel electrophoresis, they take the form of a novel series of rearrangements occurring 80 kb or more 5' to the C alpha gene. These alpha locus rearrangements are well away from any of the J alpha gene segments found in cDNA clones to date and are deleted in most mature thymocytes and functional T cell lines. Therefore they appear to represent a distinct class of rearrangement that occurs before V alpha----J alpha joining. These distinctions between the character of the TCR gene rearrangements in these cells represent useful markers in further distinguishing different stages of T cell differentiation within this compartment of early T cells. In addition, the unexpected discovery of clonal rearrangements so far away from any of the expressed J alpha gene segments, and at a stage where there is little or no stable C alpha RNA present, has interesting implications for the hierarchy of TCR gene expression.

Structure of amplified DNA, analyzed by pulsed field gradient gel electrophoresis

Pulsed field gradient electrophoresis allows the separation of large DNA molecules up to 2,000 kilobases (kb) in length and has the potential to close the resolution gap between standard electrophoresis of DNA molecules (smaller than 50 kb) and standard cytogenetics (larger than 2,000 kb). We have analysed the amplified DNA in four cell lines containing double minute chromosomes (DMs) and two lines containing homogeneously staining regions. The cells were immobilized in agarose blocks, lysed, deproteinized, and the liberated DNA was digested in situ with various restriction endonucleases. Following electrophoretic separation by pulsed field gel electrophoresis, the DNA in the gel was analysed by Southern blotting with appropriate probes for the amplified DNA. We find that the DNA in intact DMs is larger than 1,500 kb. Our results are also compatible with the notion that the DNA in DMs is circular, but this remains to be proven. The amplified segment of wild-type DNA covers more than 550 kb in all lines and possibly up to 2,500 kb in some. We confirm that the repeat unit is heterogeneous in some of the amplicons. In two cell lines, however, with low degrees of gene amplification, we find no evidence for heterogeneity of the repeats up to 750 (Y1-DM) and 800 kb (3T6-R50), respectively. We propose that amplicons start out long and homogeneous and that the heterogeneity in the repeat arises through truncation during further amplification events in which cells with shorter repeats have a selective advantage. Even if the repeats are heterogeneous, however, pulsed field gradient gels can be useful to establish linkage of genes over relatively short chromosomal distances (up to 1,000 kb). We discuss some of the promises and pitfalls of pulsed field gel electrophoresis in the analysis of amplified DNA.

A large inverted duplication allows homologous recombination between chromosomes heterozygous for the proximal t complex inversion

We have examined the molecular organization of a region of mouse chromosome 17 that allows homologous recombination between wild-type and t haplotype chromosomes across a large inversion. We have used a combination of genetic mapping of restriction fragment length polymorphisms, molecular characterization of cloned regions isolated on overlapping cosmids, and subchromosomal restriction mapping using the pulsed field gel technique. Our analyses show that the wild-type form of chromosome 17 contains an inverted duplication of an element of at least 650 kb that is present in only one copy in the t haplotype form. Two chromosomes, th45 and tAE5, arose by homologous recombination across the element that is present in both chromosomal variants in the same orientation.

Coincident multiple activations of the same surface antigen gene in Trypanosoma brucei

Trypanosomes with a coat of variant surface glycoprotein (VSG) 118, consistently appear around day 20 when a rabbit is infected with Trypanosoma brucei strain 427. There is a single chromosome-internal gene for VSG 118 and this is activated by duplicative transposition to a telomeric expression site. We show here that the expression-linked extra copy of VSG gene 118 in a day 18 population of a chronic infection is heterogeneous, and we infer that the population is not monoclonal but is the result of multiple independent activations of the 118 gene. We show that the heterogeneity of expression-linked extra copies is also present in other trypanosome populations expressing chromosome-internal VSG genes. We present a model for the timing of VSG gene activation during chronic infection that emphasizes two features: the relative activation and inactivation frequencies of different expression sites, and the degree of homology of the sequences flanking VSG genes with expression sites.

Molecular weight separation of very large DNA

Gel electrophoresis has many applications in parasitology, especially for the separation of enzymes, immunoglobulins and DNA, but the ability to separate molecules based on size is usually restricted to within the upper and lower ranges o f molecular weight. These limitations are particularly evident in mocromolecular DNA electrophoresis, although recent innovations in ogorose gel electrophoresis have substantially reduced these boundaries and are permitting the separation of very large DNA molecules and intact chromosomes of many organisms. In this article, Hugh Dawkins explains these techniques and their principle variants.

Long-range restriction map around the Duchenne muscular dystrophy gene

Duchenne muscular dystrophy is an X-linked recessive disease affecting about 1 in 4,000 newborn boys. As in many other inherited diseases, the biochemical basis of the condition is unknown, and as yet there is no effective treatment. Translocations, deletions and other mutations leading to the DMD phenotype are distributed over a chromosomal area of large, but unknown size. Using pulsed-field gradient gel electrophoresis, we have now determined restriction maps of a major fraction of this area, covering two regions of three million basepairs in total, and used it to determine the position of several probes linked to DMD. The maps establish physical distances between structural changes associated with the DMD phenotype and provide evidence for a CpG-rich island proximal to the area containing translocations and deletions associated with the DMD phenotype.

Mapping of the class II region of the human major histocompatibility complex by pulsed-field gel electrophoresis

The class II region of the human major histocompatibility complex (MHC) encodes a polymorphic set of cell surface glycoproteins involved in the regulation of the immune response. Each glycoprotein is a heterodimer composed of a alpha-chain of relative molecular mass (Mr) 34,000 (34 K) and a beta-chain of Mr = 28K. The products of the class II region have been characterized by the mixed lymphocyte reaction, serology, primed lymphocyte typing and DNA cloning. DR, DQ and DP, three subregions containing both alpha- and beta-chains, and two additional loci, DZ alpha and DO beta, locate this gene cluster on the short arm of chromosome 6. The precise genomic organization of these loci have been difficult to determine. Here we describe the use of pulsed-field gel electrophoresis together with restriction endonucleases having few genomic restriction sites and Southern blotting, to determine the order of the subregions and to derive a map for the human class II region. The order of these loci is similar to that of the homologous loci in the murine class II region. Our study establishes the use of pulsed-field gel electrophoresis in mapping large regions of the genome in higher eukaryotes.