Relationships among 3 Kochia species based on PCR-generated molecular sequences and molecular cytogenetics.

Forage kochia (Kochia prostrata ssp. virescens 'Immigrant' is native to the arid and semiarid regions of central Eurasia. It was introduced into the United States in 1966 as PI 314929 and released as a perennial forage shrub in 1984. Kochia americana is a perennial native to the United States, whereas Kochia scorparia is an introduced annual species that became a weed. To assess both the breeding potential and the possibility of genetic contamination, relationships among the 3 Kochia species were analyzed using random amplified polymorphic DNA (RAPD) markers, sequence tagged site (STS) marker sequences of the chloroplast NADH dehydrogenase gene (ndhF), genomic in situ hybridization (GISH), and multicolor fluorescence in situ hybridization (MC-FISH). Seventy decamer random primers yielded 458 polymorphic bands from 9 plants of K. americana, 20 plants of K. prostrata, and 7 plants of K. scoparia. Fifty-four and 55 species-specific RAPD markers were identified for K. americana and K. prostrata, whereas 80 RAPD markers were specific to K. scoparia. Based on the presence or absence of informative RAPD markers, the 3 species always grouped into 3 distinct clusters in a NTSYSpc2.01b-generated dendrogram. The same relationships were found among the 3 Kochia species based on ndhF DNA sequence divergence. Using a set of 7 STS markers that can identify each Kochia species, we did not find a single interspecific hybrid from artificial hybridizations among the 3 Kochia species. In GISH studies, chromosomes of 1 species fluoresced in green only when they were probed by genomic DNA of the same species. Cross-hybridization by genomic DNA of another species was not observed. In FISH studies using pTa71 (for 18S-5.8S-26S rDNAs) and pScT7 (for 5S rDNA) as probes, there were 1, 1 and 3 pTa71 sites and 2, 1, and 1 pScT7 sites in each haplome of K. prostrata, K. americana, and K. scoparia, respectively. It is concluded that these 3 Kochia species are so genomically distinct that gene introgression among them would be extremely rare.     

SEGMENT: identifying compositional domains in DNA sequences

MOTIVATION: DNA sequences are formed by patches or domains of different nucleotide composition. In a few simple sequences, domains can simply be identified by eye; however, most DNA sequences show a complex compositional heterogeneity (fractal structure), which cannot be properly detected by current methods. Recently, a computationally efficient segmentation method to analyse such nonstationary sequence structures, based on the Jensen-Shannon entropic divergence, has been described. Specific algorithms implementing this method are now needed. RESULTS: Here we describe a heuristic segmentation algorithm for DNA sequences, which was implemented on a Windows program (SEGMENT). The program divides a DNA sequence into compositionally homogeneous domains by iterating a local optimization procedure at a given statistical significance. Once a sequence is partitioned into domains, a global measure of sequence compositional complexity (SCC), accounting for both the sizes and compositional biases of all the domains in the sequence, is derived. SEGMENT computes SCC as a function of the significance level, which provides a multiscale view of sequence complexity.     

Retroviral integrase domains: DNA binding and the recognition of LTR sequences.

Integration of retroviral DNA into the host chromosome requires a virus-encoded integrase (IN). IN recognizes, cuts and then joins specific viral DNA sequences (LTR ends) to essentially random sites in host DNA. We have used computer-assisted protein alignments and mutagenesis in an attempt to localize these functions within the avian retroviral IN protein. A comparison of the deduced amino acid sequences for 80 retroviral/retrotransposon IN proteins reveals strong conservation of an HHCC N-terminal 'Zn finger'-like domain, and a central D(35)E region which exhibits striking similarities with sequences deduced for bacterial IS elements. We demonstrate that the HHCC region is not required for DNA binding, but contributes to specific recognition of viral LTRs in the cutting and joining reactions. Deletions which extend into the D(35)E region destroy the ability of IN to bind DNA. Thus, we propose that the D(35)E region may specify a DNA-binding/cutting domain that is conserved throughout evolution in enzymes with similar functions.     

PRoMT: inferring demographic history from DNA sequences

SUMMARY: I describe a parallel implementation of Rogers' mismatch algorithm, a method for making inferences about demographic history from DNA sequence data. The program is distributed on clusters of workstations, providing a substantial speedup and low execution times on large numbers of nodes. AVAILABILITY: Source code and documentation are available at http://mombasa.anthro.utah.edu/wooding/ CONTACT: stephen.wooding@anthro.utah.edu     

Detection and resolution of closely related satellite DNA sequences by molecular cloning.

Highly repeated satellite DNAs often consist of mixtures of DNAs with closely related repeating sequences. By cloning individual molecules we have resolved the 1.705 g/cm³ satellite DNA of Drosophila melanogaster into two distinct components: poly$\text{d}\text{A-A-G-A-G}\text{T-T-C-T-C}$ and poly$\text{d}\text{A-A-G-A-G-A-G}\text{T-T-C-T-C-T-C}$. The presence of two distinct sequences within this physically homogeneous satellite DNA had not previously been detected by standard physical, chemical, or sequencing techniques. Both cloning and direct sequence analysis suggest that the five-base-pair and seven-base-pair repeating units reside on separate molecules and are not interspersed with each other.     

Characterization of the Nicotiana tabacum L. genome by molecular cytogenetics

Nicotiana tabacum (2n=48) is a natural amphidiploid with component genomes S and T. We used non-radioactive in situ hybridization to provide physical chromosome markers for N. tabacum, and to determine the extant species most similar to the S and T genomes. Chromosomes of the S genome hybridized strongly to biotinylated total DNA from N. sylvestris, and showed the same physical localization of a tandemly repeated DNA sequence, HRS 60.1, confirming the close relationship between the S genome and N. sylvesfris. Results of dot blot and in situ hybridizations of N. tabacum DNA to biotinylated total genomic DNA from N. tomentosiformis and N. otophora suggested that the T genome may derive from an introgressive hybrid between these two species. Moreover, a comparison of nucleolus-organizing chromosomes revealed that the nucleolus organizer region (NOR) most strongly expressed in N. tabacum had a very similar counterpart in N. otophora. Three different N. tabacum genotypes each had up to 9 homozygous translocations between chromosomes of the S and T genomes. Such translocations, which were either unilateral or reciprocal, demonstrate that intergenomic transfer of DNA has occurred in the amphidiploid, possibly accounting for some results of previous genetic and molecular analyses. Molecular cytogenetics of N. tabacum has identified new chromosome markers, providing a basis for physical gene mapping and showing that the amphidiploid genome has diverged structurally from its ancestral components.     

ADAPT: a molecular mechanics approach for studying the structural properties of long DNA sequences.

We describe an original approach to determining sequence-structure relationships for DNA. This approach, termed ADAPT, combines all-atom molecular mechanics with a multicopy algorithm to build nucleotides that contain all four standard bases in variable proportions. These nucleotides enable us to search very rapidly for base sequences that energetically favor chosen types of DNA deformation or chosen DNA-protein or DNA-ligand interactions. Sequences satisfying the chosen criteria can be found by energy minimization, combinatorial sequence searching, or genome scanning, in a manner similar to the threading approaches developed for protein structure prediction. In the latter case, we are able to analyze roughly 2000 base pairs per second. Applications of the method to DNA allomorphic transitions, DNA deformation, and specific DNA interactions are presented.     

Unusual domains of human alphoid satellite DNA with contiguous non-satellite sequences: sequence analysis of a junction region.

The sequence organization of cloned segments of Human DNA carrying unusual domains of alphoid satellite was studied by restriction mapping, electron microscopy and base sequence analysis. In some cases restriction mapping revealed the absence of the typical 340 bp EcoR 1 dimer, although blot hybridizations showed the extensive presence of alphoid satellite. A variant monomeric construction was demonstrated by DNA sequencing. Furthermore, inverted repeats within these domains were detected by electron microscopy. In one case these were shown to be the result of interruptions in the satellite sequence by members of a family of repetitive, conserved elements.     

Diagnosis of minor chromosome modifications by molecular cytogenetics

Chromosomal in situ hybridization with radioactive probes allows the detection of single copy DNA segments of very small size. In two phenotypically normal individuals, classical chromosomal analysis revealed a small partial deletion of chromosome 18 short arm. In situ hybridization of probe D18S3, located at 18p13, showed in both instances a balanced reciprocal translocation: 46,XY,t(5;18) (p153;p112) and 46,XX,t(18;22)(p111;p11), respectively.     

Electron microscopy of supercoiled pEJ4 DNA containing homopurine.homopyrimidine sequences

Supercoiled pEJ4 DNA (a derivative of pUC19 containing an insert with 60-bp-long homopurine.homopyrimidine tract from the sea urchin P. miliaris histone gene spacer) was investigated by electron microscopy using three different spreading techniques i.e., formamide and aqueous variants of the Kleinschmidt technique and protein-free benzyldimethyl-alkyl ammonium chloride (BAC) technique at different pHs. If the specimens for electron microscopy were prepared at pH 5.6 and pH 4.0 (i.e., under conditions where the homopurine.homopyrimidine tract assumes an unusual conformation) a single thick "stem" or a "denaturation bubble" in a large number of DNA molecules were observed. No such changes were found in samples prepared at neutral pH and in linearized pEJ4 DNA prepared at pH 5.6. In specimens of a control supercoiled pUC19 DNA prepared at pH 5.6 and 4.0 practically no local changes were detected. The "denaturation bubbles" were observed by BAC techniques (probably due to secondary local DNA denaturation during the specimen preparation) while the more gentle formamide technique revealed only "stems". The "stems" were almost always positioned at the sites where the curvature of supercoiled DNA molecules occurred. The results are in agreement with presence of a protonated triplex H-form in homopurine.homopyrimidine tract bringing the first evidence of curvature or kinking of the DNA molecule connected with the occurrence of the H-form in supercoiled DNA.     

Conjugative transposition: Tn916 integrase contains two independent DNA binding domains that recognize different DNA sequences.

Transposition of the conjugative transposon Tn916 requires the activity of a protein, called Int, which is related to members of the integrase family of site-specific recombinases. This family includes phage lambda integrase as well as the Cre, FLP and XerC/XerD recombinases. Different proteins, consisting of fragments of Tn916 Int protein fused to the C-terminal end of maltose binding protein (MBP) were purified from Escherichia coli. DNase I protection experiments showed that MBP-INT proteins containing the C-terminal end of Int bound to the ends of the transposon and adjacent plasmid DNA. MBP-INT proteins containing the N-terminal end of Int bound to sequences within the transposon close to each end. Competition binding experiments showed that the sites recognized by the C- and N-terminal regions of Int did not compete with each other for binding to MBP-INT. We suggest that Tn916 and related conjugative transposons are unique among members of the integrase family of site-specific recombination systems because the presence of two DNA binding domains in the Int protein might allow Int to bridge recombining sites, and this bridging seems to be the sole mechanism ensuring that only correctly aligned molecules undergo recombination.