Sialic acid and sialyl‐lactose glyco‐conjugates: design,synthesis and binding assays to lectins and swine influenza H1N1 virus

The terminal parts of the influenza hemagglutinin (HA) receptors α2,6‐ and α2,3‐sialyllactoses were conjugated to an artificial carrier, named sequential oligopeptide carrier (SOC₄), to formulate human and avian receptor mimics, respectively. SOC₄, formed by the tripeptide unit Lys‐Aib‐Gly, adopts a rigid helicoids‐type conformation, which enables the conjugation of biomolecules to the Lys‐N^εH₂ groups. By doing so, it preserves their initial conformations and functionalities of the epitopes. We report that SOC₄‐glyco‐conjugate bearing two copies of the α2,6‐sialyllactose is specifically recognized by the biotinylated Sambucus nigra (elderberry) bark lectin, which binds preferentially to sialic acid in an α2,6‐linkage. SOC₄‐glyco‐conjugate bearing two copies of the α2,3‐sialyllactose was not recognized by the biotinylated Maackia amurensis lectin, despite its well‐known α2,3‐sialyl bond specificity. However, preliminary immune blot assays showed that H1N1 virus binds to both the SOC₄‐glyco‐conjugates immobilized onto nitrocellulose membrane. It is concluded that Ac‐SOC₄[(Ac)₂,(3′SL‐Aoa)₂]‐NH₂ 5 and Ac‐SOC₄[(Ac)₂,(6′SL‐Aoa)₂]‐NH₂ 6 mimic the HA receptors. These findings could be useful for easy screening of binding and inhibition assays of virus–receptor interactions. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Detection of a Salmonella enterica serovar California strain spreading in spanish feed mills and genetic characterization with DNA microarrays

We performed an epidemiological study on Salmonella isolated from raw plant-based feed in Spanish mills. Overall, 32 different Salmonella serovars were detected. Despite its rare occurrence in humans and animals, Salmonella enterica serovar California was found to be the predominant serovar in Spanish feed mills. Different typing techniques showed that isolates of this serovar were genetically closely related, and comparative genomic hybridization using microarray technology revealed 23 S. enterica serovar Typhimurium LT2 gene clusters that are absent from serovar California.     

Genetic and environmental variation of seed weight in Trichloris species (Chloridoideae,Poaceae) and its association with seedling stress tolerance

Background: Seed weight is a key fitness-related trait associated with plant adaptation and is commonly targeted in plant breeding.

Aims: We evaluated seed weight variation within and between Trichloris crinita and Trichloris pluriflora across their geographical ranges in Argentina.

Methods: Genetic variation in seed weight was evaluated through a common garden experiment. To examine the possible role of such variation in local adaptation, we compared the seed weight of plants of populations raised in the common garden with seed weight variation and ecogeographical variables across their original habitats. We also evaluated experimentally the effects of seed weight variation upon osmotic stress tolerance at germination.

Results: Variation in seed weight existed in both species. Such variation had a genetic basis in T. crinita related to several ecogeographical variables. Larger seeds of T. crinita were associated with more stressful environments and produced larger seedlings under both osmotic stress and non-stress conditions.

Conclusions: Our results suggest that seed weight variation in T. crinita is likely adaptive, with large seed having an advantage during early developmental stages, particularly under stressful conditions. Such knowledge should prove helpful in selecting the most suitable populations for restoration and plant breeding.     

Transposition of IS91 does not generate a target duplication.

We determined the DNA sequences surrounding the junctions of IS91 in two insertion derivatives: pSU234 (pACYC184::IS91) and pSU240 (pBR322::IS91). The termini of IS91 consist of two imperfect inverted repeats eight base pairs long. Their sequence is 5'-TCGAGTAGG. . . CCTATCGA-3'. Insertion of IS91 did not generate direct repetitions in the target DNAs.     

Integrated R2 sequence in mitochondria of fertile B37N maize encodes and expresses a 130 kD polypeptide similar to that encoded by the S2 episome of S-type male sterile plants.

Expression of a 130 kDa protein from open reading frame 1 of the integrated form of the R2 mitochondrial plasmid in normal mitochondria of B37 and other inbred lines is described. The protein appears identical to that synthesized by the closely related S2 episome found in cytoplasmic male sterile maize of the S type. Protein was detected using antisera raised against a beta-galactosidase:ORF1 fusion product containing the most antigenic region of the ORF1 product. Detection of this protein is in contrast to previous reports that mitochondria of normal, male-fertile lines either do not contain this protein, or that there are 11 in-frame stop codons in the reading frame. The integrated R2 of B37N was cloned and this region sequenced, confirming that a continuous open reading frame existed. These results are discussed in relation to the possible role of the S-type episomes in causing cytoplasmic male sterility.     

An S1 episomal gene of maize mitochondria is expressed in male sterile and fertile plants of the S-type cytoplasm

Summary Maize mitochondria of cytoplasmic male sterile (cms-S) plants contain two linear episomes, S1 (6397 bp) and S2 (5453 bp). S1 contains three long open reading frames URF2 (1017 bp), URF3 (2782 bp) and URF4 (768 bp). We have demonstrated that the URF3 sequence of S1 encodes a protein with an apparent molecular weight of 103 kDa which is found in cms-S but undetectable in cms-T, cms-C or normal (fertile) mitochondria. A translational fusion containing the 5 terminus of the lacZ gene and 800 bp of the 3 end of URF3 was isolated from a cms-S mitochondrial genomic library in the expression vector gt11. Polyclonal antibodies raised against the resulting fusion protein immunoprecipitated a 103 kDa polypeptide from among [³⁵S]-methionine-labeled cms-S mitochondrial proteins but not from normal mitochondrial proteins. The mitochondria of fertile F1 plants resulting from a cross between B37 cms-S and Ky21 (universal restorer) contain as much of this 103 kDa protein as is observed in sterile cms-S mitochondria. The mitochondria of fertile cytoplasmic revertants from cms-RD and cms-LM in a WF9 nuclear background also synthesized the 103 kDa protein. We conclude that the URF3 sequence of the S1 episome is expressed in vivo and that the presence of its gene product in maize mitochondria is not sufficient to confer the male sterile phenotype.     

The molecular relatedness among alpha-hemolytic plasmids from various incompatibility groups

Deoxyribonucleic acid (DNA) reassociation studies among α-hemolytic (Hly) plasmids from FVI and FIII–IV incompatibility groups showed a close similarity between the nucleotide sequences of plasmids from the same group. With respect to R plasmids from the F overgroup, they have 20–26 Mdal in common, an amount of DNA close to the amount involved in the traF operon. No more extensive sequence homology was found between pSU316 (IncFIII–IV) and the incompatible plasmids ColB-K98 (IncFIII) or R124 (IncFIV). The IncIα I2 plasmid pSU5 has only the α-hemolytic region (5 Mdal) in common with plasmid pSU316 but it is much more closely related to IncFVI plasmids where the DNA in common amounts to 22 Mdal. Finally, the genetically unrelated plasmid pSU233 shares 66% of its nucleotide sequences (40 Mdal) with the IncFVI plasmids and has 16–23 Mdal in common with various F-like plasmids.     

Incompatibility among alpha-hemolytic plasmids studied after inactivation of the alpha-hemolysin gene by transposition of Tn802.

Five α-hemolytic plasmids were studied with respect to their molecular and genetic properties. Their molecular weights ranged from 48 to 93 Mdal. Digestion with HindIII restriction endonuclease indicated that they were all clearly different plasmids although similarities in their band patterns were observed. Plasmids pSU1, pSU105, and pSU316 produce F-like pili. Incompatibility studies between Hly plasmids were prevented by lack of markers other than α-hemolysin production. In order to overcome this problem, the inactivating properties of the transposable element Tn802 were used. Several Hly plasmids that have lost the ability to produce α-hemolysin were isolated after insertion of the ampicillin transposon Tn802. Incompatibility between the parental plasmids and their Tn802 derivatives suggests that α-hemolytic plasmids have spread over, at least, four incompatibility groups. Plasmids pSU1 and pSU105 were found to be incompatible with Hly-P212, the only representative, so far, of IncFVI. Plasmid pSU316 was incompatible both with ColB-K98 and R124, which suggests the existance of a FIII-FIV incompatibility complex. In addition, pSU5 and pSU233 were compatible with each other and with pSU316, pSU1, pSU105, and Hly-P212. They also produce a different type of pili from this test plasmids.     

The Rho family GTPase Cdc42 regulates the activation of Ras/MAP kinase by the exchange factor Ras-GRF

The Ras guanine-nucleotide exchange factor Ras-GRF/Cdc25(Mn) harbors a complex array of structural motifs that include a Dbl-homology (DH) domain, usually found in proteins that interact functionally with the Rho family GTPases, and the role of which is not yet fully understood. Here, we present evidence that Ras-GRF requires its DH domain to translocate to the membrane, to stimulate exchange on Ras, and to activate mitogen-activated protein kinase (MAPK). In an unprecedented fashion, we have found that these processes are regulated by the Rho family GTPase Cdc42. We show that GDP- but not GTP-bound Cdc42 prevents Ras-GRF recruitment to the membrane and activation of Ras/MAPK, although no direct association of Ras-GRF with Cdc42 was detected. We also demonstrate that catalyzing GDP/GTP exchange on Cdc42 facilitates Ras-GRF-induced MAPK activation. Moreover, we show that the potentiating effect of ionomycin on Ras-GRF-mediated MAPK stimulation is also regulated by Cdc42. These results provide the first evidence for the involvement of a Rho family G protein in the control of the activity of a Ras exchange factor.