Changes of the DNA packaging mode during boar sperm maturation

Changes in the mode of DNA packaging in nuclei during spermatogenesis were studied by measuring of the fluorescence anisotropy decay of an ethidium dye intercalated in the DNA in whole nuclei. The nuclei were isolated from boar spermatid or sperm cells at three distinct stages of spermatogenesis: just before the completion of a maturation process in the testis (late spermatid), immediately after a subsequent transformation into spermatozoa (caput spermatozoon), and after full maturation (cauda spermatozoon). Although these three kinds of nucleus were morphologically indistinguishable from each other, the anisotropy decay detected a clear difference. In the late spermatid nuclei, in which the replacement of histones by protamine was still in progress, the anisotropy decayed extensively. The decay suggested that the DNA in the spermatid nuclei contained very flexible regions, in which the interaction of the DNA and proteins may be weak. The rapid and extensive anisotropy decay was absent in the caput and cauda nuclei. The flexible portions must have turned into very rigid structure during transformation from the late spermatid into the caput spermatozoon.     

Gene-associated CpG islands in plants as revealed by analyses of genomic sequences

We screened plant genome sequences, primarily from rice and Arabidopsis thaliana, for CpG islands, and identified DNA segments rich in CpG dinucleotides within these sequences. These CpG-rich clusters appeared in the analysed sequences as discrete peaks and occurred at the frequencies of one per 4.7 kb in rice and one per 4.0 kb in A. thaliana. In rice and A. thaliana, most of the CpG-rich clusters were associated with genes, which suggests that these clusters are useful landmarks in genome sequences for identifying genes in plants with small genomes. In contrast, in plants with larger genomes, only a few of the clusters were associated with genes. These plant CpG-rich clusters satisfied the criteria used for identifying human CpG islands, which suggests that these CpG clusters may be regarded as plant CpG islands. The position of each island relative to the 5'-end of its associated gene varied considerably. Genes in the analysed sequences were grouped into five classes according to the position of the CpG islands within their associated genes. A large proportion of the genes belonged to one of two classes, in which a CpG island occurred near the 5'-end of the gene or covered the whole gene region. The position of a plant CpG island within its associated gene appeared to be related to the extent of tissue-specific expression of the gene; the CpG islands of most of the widely expressed rice genes occurred near the 5'-end of the genes.     

Characterization of the rice blast resistance gene Pik cloned from Kanto51

To study similar, but distinct, plant disease resistance (R) specificities exhibited by allelic genes at the rice blast resistance locus Pik/Pikm, we cloned the Pik gene from rice cultivar Kanto51 and compared its molecular features with those of Pikm and of another Pik gene cloned from cv. Kusabue. Like Pikm, Pik is composed of two adjacent NBS-LRR (nucleotide-binding site, leucine-rich repeat) genes: the first gene, Pik1-KA, and the second gene, Pik2-KA. Pik from Kanto51 and Pik from Kusabue were not identical; although the predicted protein sequences of the second genes were identical, the sequences differed by three amino acids within the NBS domain of the first genes. The Pik proteins from Kanto51 and Kusabue differed from Pikm in eight and seven amino acids, respectively. Most of these substituted amino acids were within the coiled-coil (CC) and NBS domains encoded by the first gene. Of these substitutions, all within the CC domain were conserved between the two Pik proteins, whereas all within the NBS domain differed between them. Comparison of the two Pik proteins and Pikm suggests the importance of the CC domain in determining the resistance specificities of Pik and Pikm. This feature contrasts with that of most allelic or homologous NBS-LRR genes characterized to date, in which the major specificity determinant is believed to lie in the highly diverged LRR domain. In addition, our study revealed high evolutionary flexibility in the genome at the Pik locus, which may be relevant to the generation of new R specificities at this locus.     

Application of restriction fragment fingerprinting with a rice microsatellite sequence to assembling rice YAC clones.

To refine the current physical map of rice, we have established a restriction fragment fingerprinting method for identifying overlap between pairs of rice yeast artificial chromosome (YAC) clones and defining the physical arrangement of YACs within contiguous fragments (contigs). In this method, Southern blots of rice YAC DNAs digested with a restriction endonuclease are probed with a rice microsatellite probe, (GGC)5. The probe produces a unique fingerprint profile characteristic of each YAC clone. The profile is then digitized, processed in a computer, and a statistic that represents the degree of overlap between two YACs is calculated. The statistics have been used to detect overlaps among YAC clones, thereby filling a gap between two neighbouring contigs and organizing overlapping rice YAC clones into contiguous fragments. We applied this method to rearranging YACs that had previously been assigned to rice chromosome 6 by anchoring with RFLP markers.     

Electron transfer complex formation between oxygenase and ferredoxin components in Rieske nonheme iron oxygenase system

Carbazole 1,9a-dioxygenase (CARDO), a member of the Rieske nonheme iron oxygenase system (ROS), consists of a terminal oxygenase (CARDO-O) and electron transfer components (ferredoxin [CARDO-F] and ferredoxin reductase [CARDO-R]). We determined the crystal structures of the nonreduced, reduced, and substrate-bound binary complexes of CARDO-O with its electron donor, CARDO-F, at 1.9, 1.8, and 2.0 A resolutions, respectively. These structures provide the first structure-based interpretation of intercomponent electron transfer between two Rieske [2Fe-2S] clusters of ferredoxin and oxygenase in ROS. Three molecules of CARDO-F bind to the subunit boundary of one CARDO-O trimeric molecule, and specific binding created by electrostatic and hydrophobic interactions with conformational changes suitably aligns the two Rieske clusters for electron transfer. Additionally, conformational changes upon binding carbazole resulted in the closure of a lid over the substrate-binding pocket, thereby seemingly trapping carbazole at the substrate-binding site.     

Sphingomonas sp. strain KA1, carrying a carbazole dioxygenase gene homologue,degrades chlorinated dibenzo-p-dioxins in soil

Hybridization analysis showed that a newly isolated carbazole (CAR)-degrading bacterium Sphingomonas sp. strain KA1 did not possess the gene encoding the terminal oxygenase component (carAa) of CAR 1,9a-dioxygenase at high homology (more than 90% identity) to that of another CAR-degrader, Pseudomonas resinovorans strain CA10. However, PCR experiments using the primers for amplifying the internal fragment of the carAa gene (810 bp for strain CA10) showed that a PCR product of unexpected size (1100 bp) was amplified. Sequence analysis revealed that this DNA region contained the portion of two possible ORFs, which showed moderate homology to CarAa and CarBa from strain CA10 (61% and 40% identities at the amino acid level, respectively). Inoculation of strain KA1 into dioxin-contaminated model soil resulted in 96% and 70% degradation of 2-mono- and 2,3-dichlorinated dibenzo-p-dioxin, respectively, after 7-day incubation.     

Ordered YAC Clone Contigs Assigned to Rice Chromosomes 3 and 11

Yeast artificial chromosome (YAC) clones were arranged on thepositions of restriction fragment length polymorphism (RFLP)and sequence-tagged site (STS) markers already mapped on thehigh-resolution genetic maps of rice chromosomes 3 and 11. Froma total of 416 and 242 YAC clones selected by colony/Southernhybridization and polymerase chain reaction (PCR) analysis,238 and 135 YAC clones were located on chromosomes 3 and 11,respectively. For chromosomes 3 and 11, 24 YAC contigs and islandswith total coverage of about 46% and 12 contigs and islandswith coverage of about 40%, respectively, were assigned. Althoughmany DNA fragments of multiple copy marker sequences could notbe mapped to their original locations on the genetic map bySouthern hybridization because of a lack of RFLP, the physicalmapping of YAC clones could often assign specific locationsof such multiple copy sequences on the genome. The informationprovided here on contig formation and similar sequence distributionrevealed by ordering YAC clones will help to unravel the genomeorganization of rice as well as being useful in isolation ofgenes by map-based cloning.     

Construction of YAC Contigs on Rice Chromosome 5

A physical map of rice chromosome 5 was constructed with yeastartificial chromosome (YAC) clones along a high-resolution molecularlinkage map carrying 118 DNA markers distributed over 123.7cM of genomic DNA. YAC clones have been identified by colonyand Southern hybridization for 105 restriction fragment lengthpolymorphism (RFLP) markers and by polymerase chain reaction(PCR) screening for 8 sequence-tagged site (STS) markers and5 randomly amplified polymorphic DNA (RAPD) markers. Of 458YACs, 235 individual YACs with an average insert length of 350kb were selected and ordered on chromosome 5 from the YAC library.Forty-eight contigs covering nearly 21 Mb were formed on thechromosome 5; the longest one was 6 cM and covered 1.5 Mb. Thelength covered with YAC clones corresponded to 62% of the totallength of chromosome 5. There were many multicopy sequencesof expressed genes on chromosome 5. The distribution of manycopies of these expressed gene sequences was determined by YACSouthern hybridization and is discussed. A physical map withthese characteristics provides a powerful tool for elucidationof genome structure and extraction of useful genetic informationin rice.     

Internal motion of DNA in bacteriophages

We have investigated internal motion of DNA in bacteriophages by measuring fluorescence anisotropy decays of intercalated ethidium. The results showed large suppression of the internal motion of the inner DNA; the interhelix interaction of the DNA in the phage head is considered to enhance the effective viscosity of the DNA rod and to restrict the angle of the internal motion. Considering that the observed internal motion arises mainly from torsional motion of the DNA, we have calculated the movable angles of the torsional motion (the standard deviation of the torsional motion) of the DNA in the phage heads. The magnitude of the calculated movable angles indicates the extent of suppression of the DNA movement in the phage head; in lambda wild type phage, the DNA is packed most rigidly in the head and the motion is found to be restricted most severely. In a deletion mutant of lambda phage, whose inner DNA content is deficient by 17.6%, steric hindrance from the interhelix DNA interaction is decreased, and the DNA can move more easily. In T4 wild type phage, although the extent of condensation of the inner DNA is the same as that in lambda wild type phage, the DNA was fairly mobile. The presence of glucosylated hydroxymethylcytosine is suggested to influence the rigidity of the inner DNA or packaging mode of the DNA in the T4 head.