Polymorphism and inheritance of gliadin polypeptides in T. monococcum L.

Summary More than 80 different gliadin electrophoretic patterns (spectra) have been found in 109 accessions of the diploid wheat Triticum monococcum. Each pattern consists of 15–20 gliadin bands. Some patterns are clearly related and might arise from one another through single mutations in the gliadin-coding loci. From the analysis of 15 grains of each, only 61 accessions were found to be uniform; others consisted of two or more grain variants differing in their gliadin spectrum. An analysis of F₂ grains from three crosses between different accessions showed that groups (blocks) of components are jointly and codominantly inherited. Two independent major Gli loci were established. The close resemblance of the composition of some blocks of T. monococcum to some of those in polyploid wheats indicates that one locus in each T. monococcum genotype is located on chromosome 1A (Gli-A1) and the other on 6A (Gli-A2). However, the blocks of T. monococcum include more bands than corresponding (equivalent) blocks of polyploid wheats. Two out of 275 F₂ grains of the cross k-14244 x k-20409 were found to have gliadin spectra which can be explained as a result of intralocus recombination. Also, a second gliadin-coding locus on chromosome 1A was found in the cross k-46140 x k-46753. This locus recombines with the main Gli-A1 locus with a frequency of about 22% and was clearly analogous to the additional Gli locus found earlier on chromosome 1A of certain polyploid wheats.     

Progressive structure-based alignment of homologous proteins: Adopting sequence comparison strategies

Comparison of multiple protein structures has a broad range of applications in the analysis of protein structure, function and evolution. Multiple structure alignment tools (MSTAs) are necessary to obtain a simultaneous comparison of a family of related folds. In this study, we have developed a method for multiple structure comparison largely based on sequence alignment techniques. A widely used Structural Alphabet named Protein Blocks (PBs) was used to transform the information on 3D protein backbone conformation as a 1D sequence string. A progressive alignment strategy similar to CLUSTALW was adopted for multiple PB sequence alignment (mulPBA). Highly similar stretches identified by the pairwise alignments are given higher weights during the alignment. The residue equivalences from PB based alignments are used to obtain a three dimensional fit of the structures followed by an iterative refinement of the structural superposition. Systematic comparisons using benchmark datasets of MSTAs underlines that the alignment quality is better than MULTIPROT, MUSTANG and the alignments in HOMSTRAD, in more than 85% of the cases. Comparison with other rigid-body and flexible MSTAs also indicate that mulPBA alignments are superior to most of the rigid-body MSTAs and highly comparable to the flexible alignment methods.     

Problems of interpreting results obtained in studies of somaclonal variation in gliadin proteins in wheat

Summary It is quite likely that somacloning increases the frequency of mutations: this has, in fact, been claimed for gliadin proteins. However, in such instances it is important to distinguish between true mutations and presumed changes in regenerants due to cross pollination or admixture. We present herein arguments that some so-claimed somaclonal variants in gliadincoding genes are unlikely to be due to mutations since they would have had to involve directed changes at several loci simultaneously.     

Chromosomal control of wheat gliadin protein epitopes: analysis with specific monoclonal antibodies

Summary The genetic relationships between small clusters of monomeric alcohol-soluble wheat (Triticum aestivum L.) grain storage proteins (gliadins) were studied using a panel of monoclonal antibodies and immunoblotting, ELISA, and RIA methods. Use of Chinese Spring nullisomic-tetrasomic lines showed that several narrow-specificity antibodies bound specifically to gliadins encoded by genes located on a single chromosome. In at least one case, antibodies bound to genetic blocks of gliadins, indicating that these block members have structural homology. However, often not all gliadins of a block were recognized by an antibody. For broad-specificity antibodies and some narrow-specificity antibodies, structural genes on several chromosomes were important. Studies with several primitive wheat species indicated that, while antibodies usually bound gliadins from the same genome in bread and primitive wheats, antibodies sometimes bound proteins of quite differing mobilities in the two wheat types. Use of antibodies to identify gliadin blocks is simpler than block analysis based on performing crosses, and should be of value in monitoring genotype/end-use quality relationships.     

Analysis of protein contacts into Protein Units

Three-dimensional structures of proteins are the support of their biological functions. Their folds are maintained by inter-residue interactions which are one of the main focuses to understand the mechanisms of protein folding and stability. Furthermore, protein structures can be composed of single or multiple functional domains that can fold and function independently. Hence, dividing a protein into domains is useful for obtaining an accurate structure and function determination.     

A Note on Block Designs with Nested Rows and Columns

Block designs with nested rows and columns have been introduced by Singh and Dey (1979). This note gives some results regarding the total relative loss of information and patterns of efficiency balanced block designs with nested rows and columns in variable replications of treatments.     

SpOT the Correct Tissue Every Time in Multi-tissue Blocks

Multi-tissue paraffin blocks provide high throughput analysis with increased efficiency, experimental uniformity, and reduced time and cost. Tissue microarrays make up the majority of multi-tissue paraffin blocks, but increasingly, researchers are using non-arrayed blocks containing larger tissues from multiple individuals which can provide many of the advantages of tissue microarrays without substantial investment in planning and equipment. A critical component of any multi-tissue analysis is the orientation method used to identify each individual tissue. Although methods exist to maintain proper orientation and identification of tissues in multi-tissue blocks, most are not well-suited to non-arrayed blocks, may consume valuable space within an array and/or are difficult to produce in the standard histology laboratory. The Specimen Orientation Tag (SpOT) is a simple, low cost orientation tool that is clearly visible in paraffin blocks and all tissue sections for reliable specimen identification in arrayed and non-arrayed layouts. The SpOT provides advantages over existing orientation methods for non-arrayed blocks as it does not require any direct modification to the tissue and allows for flexibility in the arrangement of tissue pieces.     

Conformational Study Based on Simulated Annealing and 1H NMR of Peptides Comprising the Consensus Sequence Arg5-Asp-Val-Arg-Gly9: Effects of the Substitution Ser 12 by Ala 12 or of 3 Residues Deletion at the N-Terminus

Summary

A conformational search by simulated annealing has been performed on two peptides derivated from the tetradecapeptide used to isolate the Xenopus laevis skin maturation RXVRG-endoprotease. The Ala 12 derivative, obtained by substitution in the hydrophobic C terminal fragment and the undecapeptide 4–14, obtained by deletion of an acidic rich tripeptide, were studied. No unique structure has been found for the tetradecapeptide Ala 12. This structural disorganization could explain the loss of activity of the endoprotease towards the subsituted peptide. For the undecapeptide, two different models in accordance with the NMR data were found. The conformational differences between these two models are locat ed in the consensus sequence and in each case an hairpin-like conformation is observed. These results could be related to the enhanced cleavage activity of the maturation enzyme. The obtained structures are also compared with those of the original tetradecapeptide.     

Inadequacy of blocking in cultivar yield trials

Summary Based on the literature, theoretical considerations and a numerical example on triticale, Complete Randomized Blocks design is shown to be inadequate for cultivar yield trial purposes. Assumptions required for validity and convenience are shown not to be verified throughout most of the published experiments as well as in the present numerical example. It has been referred to the difficulty in forecasting homogeneity within blocks together with heterogeneity between blocks. This is difficult to achieve even in wellknown experimental fields, let alone local fields chosen at random, which leads to unacceptably low correlation between plots from block to block in each trial. Heteroscedasticity, as supported by different regression coefficients in Joint Regression Analysis, does not allow for ANOVA, unless the overall variation of soil fertility level is reduced to an amount comparable with that expected for the unknown errors. In this instance, the loss of degrees of freedom in the two-way ANOVA is known not to be compensated for by block effect deduction. The need to generalize trial results calls attention to the emphasis that should be given to cultivar performance pattern within the area they are to be released. Thus, we advocate the need for precise point evaluations in order to give accurate estimation of that pattern. Genotype-environment interaction, within situations where ecological diversity does not include stress mechanisms of different natures, can be reasonably described through its genotype-fertility level component, since specific instability, related to climatic features, is supposed to be strongly reduced by the screening process of both cultivar production and introduction. Sensitivity of the regression techniques (even through robust methods) requires a broad range of trial fertility levels and, besides an adequate number of degrees of freedom and detection of eventual remaining specific instabilities, demands an experienced evaluation of particular ecological situations; however, randomization is not required except within trials, which should be designed as completely randomized. To carry on trials beyond one year is not an a priori demand and should only be considered when very abnormal seasonal conditions occur.This research was partially supported by the Calouste Gulbenkian Foundation, Lisboa