Reduction of titanocene dichloride with dysprosium: access to a stable titanocene(ii) equivalent for phosphite-free Takeda carbonyl olefination.

The reduction of titanocene dichloride with dysprosium yields a new titanocene(ii) equivalent without the need for further stabilising ligands. This reagent can be employed in combination with dithioacetals for the olefination of different carbonyl groups and allows for a simplified all-in-one procedure.

[Organization for the coverage of the transfusional needs of patients with hemoglobinopathy at the Établissement français du sang Bretagne]. / Organisation de la prise en charge des besoins transfusionnels des patients atteints d'hémoglobinopathie à l'Établissement français du sang Bretagne.

UNLABELLED: Brittany is a low prevalence region for hemoglobinopathies. Despite of that, the number of patients is increasing each year. In 2013, 140 patients were known at the EFS Bretagne, and medical consultations are growing for 50% each year since 2011. The consequence is an increase of needs of 22% of compatible packed red blood cells. To anticipate the announced progress, various actions were implemented as study groups, creation of a new informatic prescription for red blood cells phenotyping, promotion of donation, transfusion organisation. RESULTS: Fifthty-nine percent of the 400 ABO RH-KELL, FY, JK, MNS 3, 4, red blood cells were realised on the basis of this new informatic prescription, as the 99% of the packed red blood cells identified Fy (a- b-). So, 92% of the compatible transfused packed red blood cells were already in stock when the patients needed them. CONCLUSIONS: In Brittany, that organisation leads to assume qualitative and quantitative transfusion for sickle cell disease in more than 90% of cases, with fast distribution. In the same time promotion of donation is done to increase the diversity of donors.

[Platelet transfusion: products, indications, dose, threshold and efficacy]. / Transfusion de plaquettes: produits, indications, dose, seuil, efficacité

The quality of platelet concentrates had been greatly improved since the implementation of processing techniques based on the use of the buffy-coat in the years 1980. More recently, in the last 10 years, it is in the domain of safety that the greatest advances have been done, by the introduction of platelet additive solutions, on one hand, and by the progressive availability of pathogen reduction techniques, on the other hand. These developments in quality and safety of platelet components are important, as they lead to the conclusion that nowadays, apheresis platelet concentrates and pooled random donor platelet concentrates can be considered as equivalent, the only specific indication of the former being the care of HLA or HPA allo-immunized patients. This review covers the physiological basis of prophylactic and curative platelet transfusions, and the means to evaluate their efficacy. The main investigations that are necessary to perform in the event of an inefficient prophylactic transfusion are also mentioned. Platelet transfusion is an essential part of the transfusion support in case of central thrombocytopenia, and more indications in other medical and surgical situations are well defined. The vast majority of clinical situations in which platelet transfusions are indicated have been defined in the national guidelines published in 2003 by the AFSSAPS French authority, and are still fully valid today. Therefore, only some specific domains for which recent published data are questioning our present practices are discussed, such as the use of platelet concentrates in massive transfusion. Finally, three critical factors for establishing a coherent platelet transfusion strategy are developed: the transfusion trigger for prophylactic platelet transfusion, the platelet dose, and the impact of ABO compatibility between the product and the recipient.

Comparative behavior of Ralstonia solanacearum biovar 2 in diverse plant species.

Ralstonia solanacearum causes bacterial wilt in numerous plant species worldwide. Although biovar 2 mostly affects solanaceous crops, identification of new hosts remains a matter of concern since there is still no clear-cut distinction between host and nonhost plants. In this work we provide data based on histological studies on the status of 20 plant species, most of them of potential interest in crop rotation. Plants were watered with a beta-glucuronidase-expressing derivative of R. solanacearum biovar 2, and after a month of incubation, sections of roots and stems were analyzed to localize the pathogen on surface, in cortex and/or xylem. Depending on whether the xylem was colonized or not, plants were classified as hosts or nonhosts, respectively. Hosts generally affected in a few xylem vessels or occasionally in all xylem bundles were classified as tolerant. These included some cabbage, kidney bean, and rutabaga cultivars, and the weed bittersweet nightshade (Solanum dulcamara). Nonhosts were the cultivars tested of alfalfa, barley, black radish, carrot, celery, colocynth, fennel, fiber flax, field bean, field pea, horseradish, maize, and zucchini. However, barley and maize, though nonhosts, may act as reservoirs for the pathogen. The present work constitutes a basis for further studies on cropping systems in fields where R. solanacearum has been detected.

Use of random versus apheresis platelet concentrates.

The respective use of random (RPC) and apheresis (APC) platelet concentrates is highly heterogeneous among countries, ranging from 10 to 98% RPC in countries supposed to provide a similar transfusion service to patients. Moreover, when considering each country in the past 10 years, one can observe that some have changed their policy, switching from a majority of APC to RPC or vice versa. This presentation intends to analyse which factors may impact such decisions. For many years, the only available platelet component was a RPC obtained from whole blood donation by a two centrifugation steps process, the "platelet rich plasma" or PRP method. Since the beginning of the 1970s, APCs became available, with in fact many different techniques leading to many APCs that may not be equivalent. Since the end of the 1980s, a new method of RPC preparation was developed, using the buffy-coat (BC-PC), providing a blood component with highly preserved platelet functions as compared to RPCs prepared by the PRP technique. Finally, the use of each of these components either native, or leuco-reduced, or suspended in a storage solution, or processed with a pathogen inactivation technique adds new layers of complexity to compare them. Innumerable references can be found in the literature describing in vitro functional parameters of platelet concentrates. Although it is clear that BC-RPC retain much more their in vitro functions than PRP-RPC, indicating that no one should use the latter any more, it is much more difficult to distinguish differences between other PCs. Conversely, only a very few studies have been published related to a comparison of clinical efficacy of RPC versus APC, the endpoints being mainly CCI. Similarly to the in vitro studies, although RPC prepared with the PRP method show the lowest CCIs, no clear difference exists between "modern" RPC and APC. Another factor that may impact policy decision is the occurrence of adverse reactions in recipients. When considering only comparable data, for example leuco-reduced RPC versus leuco-reduced APC, there is now evidence that the latter is more associated with adverse reactions in recipients: data from hemovigilance in France show that, although no difference is noted for febrile non haemolytic transfusion reactions, nor for bacteria contamination, the incidence of allergic adverse reactions is about four times higher with APC as compared with RPC. Other aspects may impact the decision: the fact that using APC in place of RPC reduces the total donor exposure of patients was considered critical in some countries to reduce the risk of transmission of blood transmissible disease. Finally, the cost of the components, much higher for APC may be considered.

Synthesis and application of chiral P,N-ligands with pseudo-meso and pseudo-C(2) symmetry.

[structure: see text] Two diastereoisomeric P,N-ligands, (S,S)-1 and (R,S)-1, were synthesized and assessed in palladium-catalyzed allylic alkylations. With rac-1,3-diphenylpropenyl acetate as substrate, ligand (S,S)-1, with "pseudo-C(2)" symmetry, exhibited higher reactivity and higher enantioselectivity than the "pseudo-meso" ligand (R,S)-1, whereas reversal reactivity and selectivity were observed with rac-3-cyclohexenyl acetate.

Saprophytic intracellular rhizobia in alfalfa nodules.

In indeterminate alfalfa nodules, the establishment of the senescent zone IV, in which both symbionts undergo simultaneous degeneration, has been considered, until now, as the end point of the symbiotic interaction. However, we now describe an additional zone, zone V, proximal to the senescent zone IV and present in alfalfa nodules more than 6 weeks old. In zone V, a new round of bacterial release occurs from remaining infection threads, leading to the reinvasion of plant cells that have completely senesced. These intracellular rhizobia are rod shaped and do not display the ultrastructural differentiation features of bacteroids observed in the more distal zones of the nodule. Interestingly, we have found that oxygen is available in zone V at a concentration compatible with both bacterial development and nitrogen fixation gene expression in newly released rhizobia. However, this expression is not correlated with acetylene reduction. Moreover, the pattern of nifH expression in this zone, as well as new data relating to expression in zone II, strongly suggest that nifH transcription in the nodule is under the control of a negative regulator in addition to oxygen. Our results support the conclusion that zone V is an ecological niche where intracellular rhizobia take advantage of the interaction for their exclusive benefit and live as parallel saprophytic partners. The demonstration of such an advantage for rhizobia in nodules was the missing evidence that Rhizobium-legume interactions are indeed symbiotic and, in particular, suggests that benefits to the two partners are associated with different developmental stages within the nodule.

Ralstonia solanacearum produces hrp-dependent pili that are required for PopA secretion but not for attachment of bacteria to plant cells.

As in many other Gram-negative plant pathogenic bacteria, the Ralstonia solanacearum hrp genes are involved in the production of a type III secretion apparatus that allows the translocation of PopA protein to the external medium. Here, we show that hrp genes are also involved in the biogenesis of pili that are mainly composed of the HrpY protein. These pili are produced at one pole of the bacterium and are also released into the external medium where they can form very long straight bundles. An hrpY mutant is defective in pilus production, impaired in interactions with plants and in secretion of the PopA protein but not in attachment to plant cells.

The hrpB and hrpG regulatory genes of Ralstonia solanacearum are required for different stages of the tomato root infection process.

hrp genes, encoding type III secretion machinery, have been shown to be key determinants for pathogenicity in the vascular phytopathogenic bacterium Ralstonia solanacearum GMI1000. Here, we show phenotypes of R. solanacearum mutant strains disrupted in the prhJ, hrpG, or hrpB regulatory genes with respect to root infection and vascular colonization in tomato plants. Tests of bacterial colonization and enumeration in tomato plants, together with microscopic observations of tomato root sections, revealed that these strains display different phenotypes in planta. The phenotype of a prhJ mutant resembles that of the wild-type strain. An hrpB mutant shows reduced infection, colonization, and multiplication ability in planta, and induces a defense reaction similar to a vascular hypersensitive response at one protoxylem pole of invaded plants. In contrast, the hrpG mutant exhibited a wild-type level of infection at secondary root axils, but the ability of the infecting bacteria to penetrate into the vascular cylinder was significantly impaired. This indicates that bacterial multiplication at root infection sites and transit through the endodermis constitute critical stages in the infection process, in which hrpB and hrpG genes are involved. Moreover, our results suggest that the hrpG gene might control, in addition to hrp genes, other functions required for vascular colonization.

Specific flavonoids promote intercellular root colonization of Arabidopsis thaliana by Azorhizobium caulinodans ORS571.

The ability of Azorhizobium caulinodans ORS571 and other diazotrophic bacteria to internally colonize roots of Arabidopsis thaliana has been studied. Strains tagged with lacZ or gusA reporter genes were used, and the principal colonization sites were found to be the points of emergence of lateral roots, lateral root cracks (LRCs). High frequencies of colonization were found; 63 to 100% of plants were colonized by ORS571, and 100% of plants were colonized by Herbaspirillum seropedicae. After LRCs were colonized, bacteria moved into intercellular spaces between the cortical and endodermal cell layers. Specific flavonoids, naringenin and daidzein, at 5 x 10(-5) M, significantly promoted colonization by ORS571. By using a nodC and a nodD mutant of ORS571, it was shown that neither Nod factors nor NodD are involved in colonization or flavonoid stimulation of colonization. Flavonoids did not appear to be stimulating LRC colonization by their activity as nutritional factors. LRC and intercellular colonization by H. seropedicae was stimulated by naringenin and daidzein at the same concentration that stimulated colonization by ORS571.

Root nodulation of Sesbania rostrata.

The tropical legume Sesbania rostrata can be nodulated by Azorhizobium caulinodans on both its stem and its root system. Here we investigate in detail the process of root nodulation and show that nodules develop exclusively at the base of secondary roots. Intercellular infection leads to the formation of infection pockets, which then give rise to infection threads. Concomitantly with infection, cortical cells of the secondary roots dedifferentiate, forming a meristem which has an "open-basket" configuration and which surrounds the initial infection site. Bacteria are released from the tips of infection threads into plant cells via "infection droplets," each containing several bacteria. Initially, nodule differentiation is comparable to that of indeterminate nodules, with the youngest meristematic cells being located at the periphery and the nitrogen-fixing cells being located at the nodule center. Because of the peculiar form of the meristem, Sesbania root nodules develop uniformly around a central axis. Nitrogen fixation is detected as early as 3 days following inoculation, while the nodule meristem is still active. Two weeks after inoculation, meristematic activity ceases, and nodules then show the typical histology of determinate nodules. Thus, root nodule organogenesis in S. rostrata appears to be intermediate between indeterminate and determinate types.

Correlation between ultrastructural differentiation of bacteroids and nitrogen fixation in alfalfa nodules.

Bacteroid differentiation was examined in developing and mature alfalfa nodules elicited by wild-type or Fix- mutant strains of Rhizobium meliloti. Ultrastructural studies of wild-type nodules distinguished five steps in bacteroid differentiation (types 1 to 5), each being restricted to a well-defined histological region of the nodule. Correlative studies between nodule development, bacteroid differentiation, and acetylene reduction showed that nitrogenase activity was always associated with the differentiation of the distal zone III of the nodule. In this region, the invaded cells were filled with heterogeneous type 4 bacteroids, the cytoplasm of which displayed an alternation of areas enriched with ribosomes or with DNA fibrils. Cytological studies of complementary halves of transversally sectioned mature nodules confirmed that type 4 bacteroids were always observed in the half of the nodule expressing nitrogenase activity, while the presence of type 5 bacteroids could never be correlated with acetylene reduction. Bacteria with a transposon Tn5 insertion in pSym fix genes elicited the development of Fix- nodules in which bacteroids could not develop into the last two ultrastructural types. The use of mutant strains deleted of DNA fragments bearing functional reiterated pSym fix genes and complemented with recombinant plasmids, each carrying one of these fragments, strengthened the correlation between the occurrence of type 4 bacteroids and acetylene reduction. A new nomenclature is proposed to distinguish the histological areas in alfalfa nodules which account for and are correlated with the multiple stages of bacteroid development.

The Rhizobium meliloti host range nodQ gene encodes a protein which shares homology with translation elongation and initiation factors.

The Rhizobium meliloti nod region IIb is involved in host-range determination: (i) the presence of region IIb is necessary for transfer of alfalfa root hair curling ability to Rhizobium leguminosarum biovar trifolii; (ii) a mutation in region IIb extends the R. meliloti infection host range to Vicia sativa nigra; (iii) dominance of R. meliloti nod genes over R. leguminosarum biovar viciae nod genes is abolished by mutations in region IIb. The nucleotide sequence of this region has been determined. Genes corresponding to the two open reading frames identified are designated nodP and nodQ. The predicted amino acid sequence of the NodQ protein shows homology with translation initiation and elongation factors. The consensus sequence involved in the GTP-binding domain is conserved.

Rhizobium meliloti host range nodH gene determines production of an alfalfa-specific extracellular signal.

The Rhizobium meliloti nodH gene is involved in determining host range specificity. By comparison with the wild-type strain, NodH mutants exhibit a change in host specificity. That is, although NodH mutants lose the ability to elicit root hair curling (Hac-), infection threads (Inf-), and nodule meristem formation (Nod-) on the homologous host alfalfa, they gain the ability to be Hac+ Inf+ Nod+ on a nonhomologous host such as common vetch. Using root hair deformation (Had) bioassays on alfalfa and vetch, we have demonstrated that sterile supernatant solutions of R. meliloti cultures, in which the nod genes had been induced by the plant flavone luteolin, contained symbiotic extracellular signals. The wild-type strain produced at least one Had signal active on alfalfa (HadA). The NodH- mutants did not produce this signal but produced at least one factor active on vetch (HadV). Mutants altered in the common nodABC genes produced neither of the Had factors. This result suggests that the nodABC operon determines the production of a common symbiotic factor which is modified by the NodH product into an alfalfa-specific signal. An absolute correlation was observed between the specificity of the symbiotic behavior of rhizobial cells and the Had specificity of their sterile filtrates. This indicates that the R. meliloti nodH gene determines host range by helping to mediate the production of a specific extracellular signal.

Interference between Rhizobium meliloti and Rhizobium trifolii nodulation genes: genetic basis of R. meliloti dominance.

Transfer of an IncP plasmid carrying the Rhizobium meliloti nodFE, nodG, and nodH genes to Rhizobium trifolii enabled R. trifolii to nodulate alfalfa (Medicago sativa), the normal host of R. meliloti. Using transposon Tn5-linked mutations and in vitro-constructed deletions of the R. meliloti nodFE, nodG, and nodH genes, we showed that R. meliloti nodH was required for R. trifolii to elicit both root hair curling and nodule initiation on alfalfa and that nodH, nodFE, and nodG were required for R. trifolii to elicit infection threads in alfalfa root hairs. Interestingly, the transfer of the R. meliloti nodFE, nodG, and nodH genes to R. trifolii prevented R. trifolii from infecting and nodulating its normal host, white clover (Trifolium repens). Experiments with the mutated R. meliloti nodH, nodF, nodE, and nodG genes demonstrated that nodH, nodF, nodE, and possibly nodG have an additive effect in blocking infection and nodulation of clover.

A new symbiotic cluster on the pSym megaplasmid of Rhizobium meliloti 2011 carries a functional fix gene repeat and a nod locus.

A 290-kilobase (kb) region of the Rhizobium meliloti 2011 pSym megaplasmid, which contains nodulation genes (nod) as well as genes involved in nitrogen fixation (nif and fix), was shown to carry at least six sequences repeated elsewhere in the genome. One of these reiterated sequences, about 5 kb in size, had previously been identified as part of a cluster of fix genes located 220 kb downstream of the nifHDK promoter. Deletion of the reiterated part of this fix cluster does not alter the symbiotic phenotype. Deletion of the second copy of this reiterated sequence, which maps on pSym 40 kb upstream of the nifHDK promoter, also has no effect. Deletion of both of these copies however leads to a Fix- phenotype, indicating that both sequences carry functionally reiterated fix gene(s). The fix copy 40 kb upstream of nifHDK is part of a symbiotic cluster which also carries a nod locus, the deletion of which produces a marked delay in nodulation.

Assignment of symbiotic developmental phenotypes to common and specific nodulation (nod) genetic loci of Rhizobium meliloti.

Rhizobium meliloti nodulation (nod) genes required for specific infection and nodulation of alfalfa have been cloned. Transposon Tn5 mutagenesis defined three nod regions spanning 16 kilobases of the pSym megaplasmid. Genetic and cytological studies of 62 nodulation-defective mutants allowed the assignment of symbiotic developmental phenotypes to common and specific nod loci. Root hair curling was determined by both common (region I) and specific (region III) nod transcription units; locus IIIb (nodH gene) positively controlled curling on the homologous host alfalfa, whereas loci IIIa (nodFE) and IIIb (nodH) negatively controlled curling on heterologous hosts. Region I (nodABC) was required for bacterial penetration and infection thread initiation in shepherd's crooks, and the nodFE transcription unit controlled infection thread development within the alfalfa root hair. In contrast, induction of nodule organogenesis, which can be triggered from a distance, seemed to be controlled by common nodABC genes and not to require specific nod genes nodFE and nodH. Region II affected the efficiency of hair curling and infection thread formation.

Identification of a Rhizobium meliloti pSym2011 region controlling the host specificity of root hair curling and nodulation.

In Rhizobium meliloti 2011 nodulation genes (nod) required to nodulate specifically alfalfa are located on a pSym megaplasmid. Nod- derivatives carrying large pSym deletions were isolated. By complementation of these strains with in vivo- and in vitro-constructed episomes containing pSym of sequences and introduction of these episomes into Agrobacterium tumefaciens, we show (i) that from a region of pSym of about 360 kilobases, genes required for specific alfalfa nodulation are clustered in a DNA fragment of less than 30 kilobases and (ii) that a nod region located between nifHDK and the common nod genes is absolutely required for alfalfa nodulation and controls the specificity of root hair curling and nodule organogenesis initiation.