Phylogenetic relationships among genotypes of worldwide collection of spring and winter ryes (Secale cereale L.) determined by RAPD-PCR markers

Genetic similarities among 20 spring and 22 winter accessions of agronomically different ryes from fourteen countries were estimated by employing random amplified polymorphic DNA (RAPD) techniques. Cluster analysis of genetic distance data showed that 42 genotypes were readily classifiable into two main groups: spring and winter groups. Within the spring group, cultivars fell into a North European and an American-Chinese group. Cultivars of winter rye fell into four groups: Northern European, Russian, American and Chinese lines. A UPGMA-dendrogram based on genetic distances of cultivars of rye within the winter and spring groups showed that the clusters corresponded well to their geographical locations. The results indicated that isolation has played an important role in the evolution of rye, and that temporal isolation has influenced the genetic diversity of rye more than geographical isolation. In this experiment, RAPD proved to be a rapid, reliable and practicable method of revealing polymorphisms in rye populations.     

A simple physical model for the prediction and design of protein-DNA interactions

Protein-DNA interactions are crucial for many biological processes. Attempts to model these interactions have generally taken the form of amino acid-base recognition codes or purely sequence-based profile methods, which depend on the availability of extensive sequence and structural information for specific structural families, neglect side-chain conformational variability, and lack generality beyond the structural family used to train the model. Here, we take advantage of recent advances in rotamer-based protein design and the large number of structurally characterized protein-DNA complexes to develop and parameterize a simple physical model for protein-DNA interactions. The model shows considerable promise for redesigning amino acids at protein-DNA interfaces, as design calculations recover the amino acid residue identities and conformations at these interfaces with accuracies comparable to sequence recovery in globular proteins. The model shows promise also for predicting DNA-binding specificity for fixed protein sequences: native DNA sequences are selected correctly from pools of competing DNA substrates; however, incorporation of backbone movement will likely be required to improve performance in homology modeling applications. Interestingly, optimization of zinc finger protein amino acid sequences for high-affinity binding to specific DNA sequences results in proteins with little or no predicted specificity, suggesting that naturally occurring DNA-binding proteins are optimized for specificity rather than affinity. When combined with algorithms that optimize specificity directly, the simple computational model developed here should be useful for the engineering of proteins with novel DNA-binding specificities.     

The structure of the agaran sulfate from Acanthophora spicifera (Rhodomelaceae, Ceramiales) and its antiviral activity. Relation between structure and antiviral activity in agarans

The sulfated agaran isolated by water extraction from the red seaweed, Acanthophora spicifera (Rhodomelaceae, Ceramiales), is made up of A-units highly substituted with sulfate groups on C-2 (28-30%), sulfates on C-2 and 4,6-O-(1'-carboxyethylidene) groups (9-15%), and only the C-2 sulfate groups (5-8%) with small amounts of C-6 sulfate, 6-O-methyl, and nonsubstituted residues. B-units are formed mainly by 3,6-anhydro-alpha-L-galactose (15-16%) and its precursor, alpha-L-galactose 6-sulfate (10-17%), together with lesser amounts of 3,6-anhydro-alpha-L-galactose 2-sulfate, alpha-L-galactose 2,6-disulfate, alpha-L-galactose 2,3,6-tri-sulfate, alpha-L-galactose 2,6-disulfate 3-xylose, 2-O-methyl-alpha-L-galactose, and unsubstituted alpha-L-galactose. Small, but significant quantities of beta-D-xylose were found in all the fractions, together with small amounts to traces of D-glucose. Some of the fractions have high antiviral activity. Attempts to correlate structure and antiviral activity in agarans are presented.     

NBD-cholesterol incorporation by rat macrophages and lymphocytes: a process dependent on the activation state of the cells

The time-course of incorporation of NBD-cholesterol by macrophages (Ma) and lymphocytes (LY) obtained from untreated and thioglycollate-injected (thio) rats was investigated. NBD-cholesterol incorporation was also examined in Ma obtained from untreated rats and stimulated in vitro by lipopolysaccharide (LPS) and phorbol-myristate acetate (PMA). The same measurement was performed in LY from untreated rats stimulated by addition of LPS and concanavalin A (Con A) into the culture medium. Thio-treated Ma showed high fluorescence intensity after 1 h of incubation with NBD-cholesterol. Ma submitted concomitant to LPS and NBD-cholesterol showed low fluorescence intensity, as well as Ma stimulated with PMA. Ma from untreated and LPS pre-treated rats showed a similar time-course of incorporation. LY from thio-treated rats showed lower incorporation of NBD-cholesterol in comparison to LY from untreated rats. Incorporation was reduced when LPS was added concomitantly with NBD-cholesterol. On the other hand, LY pre-treated with LPS for 48 h showed a very high incorporation of NBD-cholesterol. Con A treatment did not cause a significant effect on NBD-cholesterol incorporation. The findings presented herein led us to conclude that the uptake of NBD-cholesterol by Ma and LY is markedly affected by the activation state of the cells.     

In vivo dynamics of the rough deal checkpoint protein during Drosophila mitosis

Rough Deal (Rod) and Zw10 are components of a complex required for the metazoan metaphase checkpoint and for recruitment of dynein/dynactin to the kinetochore. The Rod complex, like most classical metaphase checkpoint components, forms part of the outer domain of unattached kinetochores. Here we analyze the dynamics of a GFP-Rod chimera in living syncytial Drosophila embryos. Uniquely among checkpoint proteins, GFP-Rod robustly streams from kinetochores along microtubules, from the time of chromosome attachment until anaphase onset. Prometaphase and metaphase kinetochores continuously recruit new Rod, thus feeding the current. Rod flux from kinetochores appears to require biorientation but not tension because it continues in the presence of taxol. As with Mad2, kinetochore- and spindle-associated Rod rapidly turns over with free cytosolic Rod, both during normal mitosis and after colchicine treatment, with a t1/2 of 25-45 s. GFP-Rod coimmunoprecipitates with dynein/dynactin, and in the absence of microtubules both Rod and dynactin accumulate on kinetochores. Nevertheless, Rod and dynein/dynactin behavior are distinguishable. We propose that the Rod complex is a major component of the fibrous corona and that the recruitment of Rod during metaphase is required to replenish kinetochore dynein after checkpoint conditions have been satisfied but before anaphase onset.     

Differential corticostriatal plasticity during fast and slow motor skill learning in mice

BACKGROUND: Motor skill learning usually comprises "fast" improvement in performance within the initial training session and "slow" improvement that develops across sessions. Previous studies have revealed changes in activity and connectivity in motor cortex and striatum during motor skill learning. However, the nature and dynamics of the plastic changes in each of these brain structures during the different phases of motor learning remain unclear. RESULTS: By using multielectrode arrays, we recorded the simultaneous activity of neuronal ensembles in motor cortex and dorsal striatum of mice during the different phases of skill learning on an accelerating rotarod. Mice exhibited fast improvement in the task during the initial session and also slow improvement across days. Throughout training, a high percentage of striatal (57%) and motor cortex (55%) neurons were task related; i.e., changed their firing rate while mice were running on the rotarod. Improvement in performance was accompanied by substantial plastic changes in both striatum and motor cortex. We observed parallel recruitment of task-related neurons in both structures specifically during the first session. Conversely, during slow learning across sessions we observed differential refinement of the firing patterns in each structure. At the neuronal ensemble level, we observed considerable changes in activity within the first session that became less evident during subsequent sessions. CONCLUSIONS: These data indicate that cortical and striatal circuits exhibit remarkable but dissociable plasticity during fast and slow motor skill learning and suggest that distinct neural processes mediate the different phases of motor skill learning.     

Cytogenetics of genetic counseling patients in Pelotas, Rio Grande do Sul, Brazil

From 1986 to 2002, we examined the chromosomal composition of 916 patients attended by two genetic counseling services in the city of Pelotas, in the Brazilian State of Rio Grande do Sul, to determine the genetic causes of their disturbances. Patterns of G-banding using trypsin and Giemsa (GTG) and C-banding using barium and Giemsa (CBG) were studied using phytohemagglutinin M-stimulated lymphocytes cultured from peripheral blood. Among the patients, 110 had Down's syndrome, 7 had Edward's syndrome, 4 had Patau's syndrome, 29 had Turner's syndrome, 5 had Klinefelter's syndrome, and 3 had "cri-du-chat" syndrome. Abnormal chromosomes were observed in 29.3% of the patients. Most of these (56.3%) were numerical abnormalities, with the remaining being structural variants.     

Molecular characterization of bla(IMP-5), a new integron-borne metallo-beta-lactamase gene from an Acinetobacter baumannii nosocomial isolate in Portugal

Postbloom fruit drop (PFD) of citrus is caused by Colletotrichum acutatum. PFD isolates infect flower petals, induce abscission of small fruit and can cause severe yield loss on most citrus cultivars. Isolates from Key lime anthracnose (KLA) cause that disease on the Mexican lime, but also cause PFD on sweet orange. Both PFD and KLA isolates exhibited resistance to the common selection agents including hygromycin, bialaphos, benomyl and geneticin/G418. A genetic transformation system was developed for C. acutatum to confer resistance to sulfonylurea (chlorimuron ethyl) by expressing an acetolactate synthase gene (sur) cassette from Magnaporthe grisea. The protocol was tested on 11 different KLA and PFD isolates. The transformation frequencies were highly variable among isolates and among experiments (0-17.9 per microg circular DNA using 10(7) protoplasts). Southern blot analysis of transformants indicated that the plasmid vector was randomly integrated in multiple copies into the genome of C. acutatum. Addition of restriction enzymes or use of a vector with homologous sequences did not change the transformation frequencies, but tended to reduce the number integrated. Over 97% of the transformants retained the sulfonylurea resistance phenotype under non-selective conditions. Of 300 transformants tested, three were unable to cause necrotic lesions on detached Key lime leaves. The transformation method opens up opportunities for the genetic manipulation of C. acutatum.