Analysis of rice (Oryza sativa L.) genome using pulsed-field gel electrophoresis and rare-cutting restriction endonucleases

TheOryza sativa (rice) genome is small (600 to 900 megabase pairs) when compared to that of other monocotyledonous plants. Rice was the first of the major cereals to be successfully transformed and regenerated. An RFLP map with approximately 300 markers is readily available, and the DNA content per map unit is only two to three times that ofArabidopsis thaliana. Rice is also the main staple food for the majority of peoples in the world. We developed techniques for the preparation of intact genomic DNA from Indica and Japonica subspecies of rice, used statistical methods to determine which restriction endonucleases are rare-cutting, and used pulsed-field gel electrophoresis (PFE) to separate large fragments of rice DNA. Southern hybridization to blotted rice PFE gels was used to show that the digests were complete. The long-term goal of our work is to generate an integrated genetic/physical map for the rice genome, as well as helping to establish rice as a model for map-based gene cloning and genome analysis.     

Parentage determination in maize hybrids using the arbitrarily primed polymerase chain reaction (AP-PCR)

Summary Using a novel procedure based on the polymerase chain reaction, we have developed a rapid, efficient, and economical method for identifying plant genotypes. The arbitrarily primed polymerase chain reaction (AP-PCR) generates reproducible fingerprints from any organism, without the need for DNA sequence information. These fingerprints include DNA fragment polymorphisms that can be (1) used for varietal identification and parentage determination, (2) followed in segregating populations produced by crosses, (3) used as markers for the construction of genetic maps, and (4) used to generate dendograms of phylogenetic relationships, especially at the intraspecific level. AP-PCR requires only minute quantities of DNA (10–25 ng per reaction) and therefore can be used in situations in which DNA is limiting. We demonstrate the use of AP-PCR to identify inbred parents of hybrid maize plants in double-blind experiments.     

Genetic analysis of agronomic traits in a cross between sugarcane (Saccharum officinarum L.) and its presumed progenitor (S. robustum Brandes & Jesw. ex Grassl)

Saccharum robustum Brandes & Jesw. ex Grassl has been suggested as the immediate progenitor species of cultivated sugarcane (S. officinarum L.) [4]. Chromosome pairing and assortment in these two species were previously studied by genetic analysis of single-dose DNA markers in parents in and 44 F₁ progeny of a cross between euploid, meiotically regular 2n=80S. officinarum LA Purple andS. robustum Mol 5829 [2]. This same population was subsequently clonally propagated and evaluated in replicated trials for quantitative traits important to sugarcane breeders. Numbers of stalks, tasseled stalks, and stalks with smut, and the average diameter of two stalks were determined one day prior to harvest. At harvest, plant material from each plot was weighed and evaluated for pol (sucrose content) and fiber percentages. Clones were significantly different (P<0.01) for all traits analyzed. Associations of 83 single-dose arbitrarily primed PCR genetic markers with quantitative trait loci (QTL) of recorded traits was determined by single-factor ANOVA, and multiple regression. QTL analysis revealed markers significantly (P<0.05) associated with the expression of each trait analyzed. Markers associated with QTL after multiple regression were tested for digenic linear × linear epistatic interactions. The various multilocus models explained between 23% and 58% of the total phenotypic variation and 32% and 76% of the genotypic variation for the various traits. Digenic interactions were uncommon. Implications for marker-assisted selection in sugarcane and sugarcane domestication are discussed.     

A Genetic Linkage Map of Saccharum Spontaneum L. `ses 208''

The arbitrarily primed polymerase chain reaction was used to detect single-dose polymorphisms that, in turn, were used to generate a linkage map of a polyploid relative of cultivated sugarcane, Saccharum spontaneum `SES 208' (2n = 64). The mapping population was composed of 88 progeny from a cross between SES 208 and a diploidized haploid derived from SES 208 by anther culture, ADP 85-0068. This cross allowed direct analysis of meiosis in SES 208 and gametic segregation ratios to be observed. One hundred twenty-seven 10-mer oligonucleotide primers of arbitrary sequence were selected from a pool of 420 primers used to screen the mapping parents. Three hundred thirty-six of the 420 primers amplified 4,540 loci or 13.5 loci per primer. The selected 127 primers revealed 2,160 loci of which 279 were present in SES 208 and absent in ADP 85-0068 and easily scored. Two hundred and eight (74.6%) of these 279 polymorphisms were single-dose polymorphisms (i.e., they displayed 1:1 segregation, χ(2) at 98% confidence level). Linkage analysis (θ = 0.25, LOD = 9.0 for two-point analysis, then θ = 0.25, LOD = 6.0 for multipoint analysis) of single-dose polymorphisms placed them into 42 linkage groups containing at least 2 markers. These single-dose markers span 1,500 contiguous centimorgans (cM) with 32 markers remaining unlinked (15.4%). From this 208-marker map we estimated the genome size of SES 208 to be 2,550 cM. The map has a predicted coverage of 85.1% at 30 cM, meaning that any new marker placed has an 85.1% chance of being within 30 cM of an existing marker. Furthermore, we show that SES 208 behaves like an autopolyploid because (i) the ratio of single-dose markers to higher dose markers fit the assumption of autooctaploidy and (ii) the absence of repulsion phase linkages. This is the first genetic map constructed directly on a polyploid species for which no diploid relatives are known.     

The genomes of the family Rhizobiaceae: size, stability, and rarely cutting restriction endonucleases.

The lack of high-resolution genetic or physical maps for the family Rhizobiaceae limits our understanding of this agronomically important bacterial family. On the basis of statistical analyses of DNA sequences of the Rhizobiaceae and direct evaluation by pulsed-field agarose gel electrophoresis (PFE), five restriction endonucleases with AT-rich target sites were identified as the most rarely cutting: AseI (5'-ATTAAT-3'), DraI (5'-TTTAAA-3'), SpeI (5'-ACTAGT-3'), SspI (5'-AATAAT-3'), and XbaI (5'-TCTAGA-3'). We computed the sizes of the genomes of Bradyrhizobium japonicum USDA 424 and Rhizobium meliloti 1021 by adding the sizes of DNA fragments generated by SpeI digests. The genome sizes of R. meliloti 1021 and B. japonicum USDA 424 were 5,379 +/- 282.5 kb and 6,195 +/- 192.4 kb, respectively. We also compared the organization of the genomes of free-living and bacteroid forms of B. japonicum. No differences between the PFE-resolved genomic fingerprints of free-living and mature (35 days after inoculation) bacteroids of B. japonicum USDA 123 and USDA 122 were observed. Also, B. japonicum USDA 123 genomic fingerprints were unchanged after passage through nodules and after maintenance on a rich growth medium for 100 generations. We conclude that large-scale DNA rearrangements are not seen in mature bacteroids or during free-living growth on rich growth media under laboratory conditions.     

Glocal Clinical Registries: Pacemaker Registry Design and Implementation for Global and Local Integration – Methodology and Case Study

Background

The ability to apply standard and interoperable solutions for implementing and managing medical registries as well as aggregate, reproduce, and access data sets from legacy formats and platforms to advanced standard formats and operating systems are crucial for both clinical healthcare and biomedical research settings.

Purpose

Our study describes a reproducible, highly scalable, standard framework for a device registry implementation addressing both local data quality components and global linking problems.

Methods and Results

We developed a device registry framework involving the following steps: (1) Data standards definition and representation of the research workflow, (2) Development of electronic case report forms using REDCap (Research Electronic Data Capture), (3) Data collection according to the clinical research workflow and, (4) Data augmentation by enriching the registry database with local electronic health records, governmental database and linked open data collections, (5) Data quality control and (6) Data dissemination through the registry Web site. Our registry adopted all applicable standardized data elements proposed by American College Cardiology / American Heart Association Clinical Data Standards, as well as variables derived from cardiac devices randomized trials and Clinical Data Interchange Standards Consortium. Local interoperability was performed between REDCap and data derived from Electronic Health Record system. The original data set was also augmented by incorporating the reimbursed values paid by the Brazilian government during a hospitalization for pacemaker implantation. By linking our registry to the open data collection repository Linked Clinical Trials (LinkedCT) we found 130 clinical trials which are potentially correlated with our pacemaker registry.

Conclusion

This study demonstrates how standard and reproducible solutions can be applied in the implementation of medical registries to constitute a re-usable framework. Such approach has the potential to facilitate data integration between healthcare and research settings, also being a useful framework to be used in other biomedical registries.     

Estimation of the mean distance of closest approach of some heavy metal ions in aqueous solutions: some experimental and theoretical calculations

The estimation of numerical values of the mean distance of closest approach of ions, a, of heavy metal ion salts in aqueous solutions, determined from activity coefficients, as well as from different theoretical approaches, is presented and discussed.