Strong associations between plant genotypes and bacterial communities in a natural salt marsh

Although microbial communities have been shown to vary among plant genotypes in a number of experiments in terrestrial ecosystems, relatively little is known about this relationship under natural conditions and outside of select model systems. We reasoned that a salt marsh ecosystem, which is characterized by twice‐daily flooding by tides, would serve as a particularly conservative test of the strength of plant–microbial associations, given the high degree of abiotic regulation of microbial community assembly resulting from alternating periods of inundation and exposure. Within a salt marsh in the northeastern United States, we characterized genotypes of the foundational plant Spartina alterniflora using microsatellite markers, and bacterial metagenomes within marsh soil based on pyrosequencing. We found significant differences in bacterial community composition and diversity between bulk and rhizosphere soil, and that the structure of rhizosphere communities varied depending on the growth form of, and genetic variation within, the foundational plant S. alterniflora. Our results indicate that there are strong plant–microbial associations within a natural salt marsh, thereby contributing to a growing body of evidence for a relationship between plant genotypes and microbial communities from terrestrial ecosystems and suggest that principles of community genetics apply to this wetland type.     

Phytosiderophore release in bread and durum wheat genotypes differing in zinc efficiency

The effect of the zinc (Zn) nutritional status on the rate of phytosiderophore release was studied in nutrient solution over 20 days in four bread wheat (Triticum aestivum cvs. Kiraç-66, Gerek-79, Aroona and Kirkpinar) and four durum wheat (Triticum durum cvs. BDMM-19, Kunduru-1149, Kiziltan-91 and Durati) genotypes differing in Zn efficiency.Visual Zn deficiency symptoms, such as whitish-brown necrosis on leaves and reduction in plant height appeared first and more severe in Zn-inefficient durum wheat genotypes Kiziltan-91, Durati and Kunduru-1149. Compared to the bread wheat genotypes, all durum wheat genotypes were more sensitive to Zn deficiency. BDMM-19 was the least affected durum wheat genotype. Among the bread wheat genotypes, Kirkpinar was the most sensitive genotype. In all genotypes well supplied with Zn, the rate of phytosiderophore release was very low and did not exceed 1 mol 32 plants^-1 3h^-1, or 0.5 mol g^-1 root dry wt 3h^-1. However, under Zn deficiency, with the onset of visual Zn deficiency symptoms, the release of phytosiderophores was enhanced in bread wheat genotypes up to 7.5 mol 32 plants^-1 3h^-1, or 9 mol g^-1 root dry wt 3h^-1, particularly in Zn-efficient Kiraç-66, Gerek-79 and Aroona. In contrast to bread wheat genotypes, phytosiderophore release in Zn-deficient durum wheat genotypes remained at a very low rate. Among the durum wheat genotypes BDMM-19 had highest rate of phytosiderophore release. HPLC analysis of root exudates showed that 2-deoxymugineic acid (DMA) is the dominating phytosiderophore released from roots of Zn-efficient genotypes. In root extracts concentration of DMA was also much higher in Zn-efficient than in inefficient genotypes. The results demonstrate that enhanced synthesis and release of phytosiderophores at deficient Zn supply is involved in Zn efficiency in wheat genotypes. It is suggested that the expression of Zn efficiency mechanism is causally related to phytosiderophore-mediated enhanced mobilization of Zn from sparingly soluble Zn pools and from adsorption sites, both in the rhizosphere and plants.     

Effects of glucose-supplemented diets on food intake, nymphal development, and fecundity of glucose-averse, non-glucose-averse, and heterozygous strains of the German cockroach,Blattella germanica

Life history parameters were determined for glucose-averse (glu/glu), wild-type (glu+/glu+) and heterozygous (glu/glu+) genotypes of Blattella germanica (L.) (Blattodea: Blattellidae) fed diets supplemented with glucose. Glu/glu nymphs consumed less glucose-supplemented diet, gained less weight, developed slower and had a lower rate of survival than glu/glu nymphs fed the same diet without added glucose, or glu+/glu+ and glu/glu+ fed either diet. Prior to formation of the first oötheca, female glu/glu consumed less glucose-supplemented diet per day than glu+/glu+ and glu/glu+, which presumably delayed egg case production. Oötheca-bearing glu/glu and glu/glu+ females consumed less glucose-supplemented diet than glu+/glu+ females. Despite a difference in female total diet intake, there was no effect of diet or genotype on fecundity. However, the intrinsic rate of increase (r) for glulglu on unsupplemented diet was less than that of glu+/glu+ and glu/glu+, suggesting that individuals with both glu alleles may be at a selective disadvantage in environments lacking diets containing glucose plus a toxicant.     

The effect of life cycle stage and genotype on desiccation tolerance in the colonizing parthenogenetic cockroach Pycnoscelus surinamensis and its sexual ancestor P. indicus

We compared the desiccation tolerance of nymphs of diploid and triploid clones of the colonizing parthenogenetic cockroach, Pycnoscelus surinamensis, and strains of its sexual ancestor, P. indicus, as a test of the general-purpose genotype hypothesis and the polyploidy hypothesis for geographic parthenogenesis in this species complex. Desiccation tolerance is strongly associated with nymphal size. Clones of P. surinamensis are highly variable in nymphal desiccation tolerance, adjusted for body weight by analysis of covariance. This heterogeneity is mirrored by significant differences among recently isolated sublines of a lab population of P. indicus. As a group, the clones are not more tolerant than the sexual strains. Likewise, the four triploid clones were not more resistant to desiccation than the four diploid clones tested. A second experiment revealed a negative association between adult and last instar desiccation tolerance, due to developmental factors not associated with size. These patterns of variation in the sexual and parthenogenetic forms are consistent with the conclusion that extensive genetic variation in desiccation tolerance in the sexual ancestor has been preserved in the clonal lineages, but that desiccation tolerance has not been selected on strongly during the dispersal of clones of P. surinamensis.     

Genetic differentiation and phenotypic plasticity in Plantago major ssp. major. II. The effect of differences in level of irradiance on Mg2+- and Ca2+-stimulated ATPase activity from roots and shoot

Ca²⁺- and Mg²⁺-stimulated ATPase activity of the microsomal fraction of shoots and roots and the temperature dependence of the Ca²⁺-stimulated ATPase activity of the shoot of plants of two genotypes of Plantago major ssp. major L., one originating from an exposed and the other from a shaded habitat, were followed at two levels of irradiance. In addition the responses of these parameters were studied after transfer of the plants from one light condition to the other. The capacity and the optimum temperature of shoot ATPase activity were affected by irradiance during growth, in contrast to the root ATPase activity. Generally, no plastic adaptive response of the measured characteristics was observed after transfer of the plants. The remaining plasticity or stability of plant characteristics could not be interpreted as adaptive; the adaptive plastic responses were confined to the seedling stage of individuals of both genotypes. Possible mechanisms involved in plastic and adaptive responses and including phytochrome are discussed.     

Impact of groundnut rosette disease on nutritive value and elemental composition of four varieties of peanut (Arachis hypogaea)

Proximate and elemental composition of four peanut genotypes infected with groundnut rosette disease (GRD) was examined. Moisture and ash content generally decreased while fat and energy content increased in seeds from diseased plants. Protein and carbohydrate varied between seeds of diseased and healthy plants of the different varieties with no consistent pattern. Instrumental neutron activation analysis of 10 elements within leaves, stems and seeds showed elevated levels of K, Al and Cl in leaves, stems and seeds in at least three of the four varieties infected with GRD while Na was decreased in stems but increased in seeds. While significant differences were found, Mg, Mn, Ca and Zn did not show any consistent change with respect to plant part or genotype, between diseased and healthy plants. V and Fe were found at low levels in leaves and stems and not detected in seeds. This represents the first report on the effect of GRD on the nutritive quality of peanuts.     

Design,synthesis and biological evaluation of novel donepezil–coumarin hybrids as multi-target agents for the treatment of Alzheimer’s disease

Combining N-benzylpiperidine moiety of donepezil and coumarin into in a single molecule, novel hybrids with ChE and MAO-B inhibitory activity were designed and synthesized. The biological screening results indicated that most of compounds displayed potent inhibitory activity for AChE and BuChE, and clearly selective inhibition to MAO-B. Of these compounds, 5m was the most potent inhibitor for eeAChE and eqBuChE (0.87 μM and 0.93 μM, respectively), and it was also a good and balanced inhibitor to hChEs and hMAO-B (1.37 μM for hAChE; 1.98 μM for hBuChE; 2.62 μM for hMAO-B). Molecular modeling and kinetic studies revealed that 5m was a mixed-type inhibitor, which bond simultaneously to CAS, PAS and mid-gorge site of AChE, and it was also a competitive inhibitor, which occupied the active site of MAO-B. In addition, 5m showed good ability to cross the BBB and had no toxicity on SH-SY5Y neuroblastoma cells. Collectively, all these results suggested that 5m might be a promising multi-target lead candidate worthy of further pursuit.     

Wheat cultivar reactions to deleterious rhizosphere bacteria under gnotobiotic conditions

With the aim of elucidating mechanisms behind bacteria-induced deleterious effects and differential cultivar responses to bacterial inoculations, wheat seedlings were subjected to various tests under gnotobiotic conditions. Inoculation with two deleterious Pseudomonas isolates, Å 112 (fluorescent) and Å 313 (nonfluorescent), induced leaf symptoms and shoot and root growth inhibition, while inoculation with growthneutral bacteria (Serratia liquefaciens andEscherichia coli) had no such effects. Deleterious effects were induced at low inoculum densities (<10³ cells per plant), but required addition of nutrient broth in small amounts for consistency. Effects similar to those obtained with living inoculum could be induced by treating plants with sterile culture filtrates from isolate Å 313 or volatile bacterial metabolites from isolate Å 112. Wheat cultivars previously found to differ in their reaction to inoculation under non-sterile conditions, responded differentially to Å 112 and Å 313 also in the gnotobiotic assay. The results agree with the hypothesis that neither cultivar reaction nor the bacterial effects as such are mediated by interactions with an indigenous rhizosphere microflora.