Ring‐opening of azetidiniums by nucleophiles. Synthesis of polysubstituted linear amines

This microreview focuses on the nucleophilic ring‐opening of azetidiniums presenting various substitution patterns at C2, C3, and C4. In most cases, the nucleophilic ring‐opening occurred in a stereoselective and regioselective fashion producing functionalized linear amines. Experimental selectivities associated with Density Functional Theory (DFT) calculations have allowed a better understanding of the parameters governing the regioselectivities.     

Different response of an elite <Emphasis Type="Italic">Bt</Emphasis> restorer line of hybrid rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) in adaptation to nitrogen deficiency

Transgenic Bacillus thuringiensis (Bt) rice have been reported to acquire effective resistance against the target pests; however, the insertion and expression of alien Bt genes may have some unintended effects on the growth characteristics of rice. A screen-house experiment was conducted and repeated twice to investigate the growth characteristics and Bt protein expressions in two Bt rice lines [MH63 (Cry2A*) and MH63 (Cry1Ab/Ac)], which had different Bt protein expression levels in leaves, under zero nitrogen (N0) and recommended nitrogen (NR) fertilizer applications. Compared to the counterpart MH63, MH63 (Cry2A*) under N0 experienced accelerated leaf senescence and a lower internal N use efficiency (IE_N), resulting in a 23.2% decrease in grain yield and a lower accumulated biomass. These variations were revealed to be correlated to the higher ratio of the Bt protein content to the soluble protein content (BTC/SPC) with a maximum value of 4.3‰ in MH63 (Cry2A*) leaves in the late growth stage. Under NR, no differences in growth characteristics between MH63 (Cry2A*) and MH63 were found. The growth characteristics of MH63 (Cry1Ab/Ac), with a lower BTC/SPC in the late growth stage compared to MH63 (Cry2A*), were identical to those of MH63 under the two N applications. Results show that the transgenic Bt rice MH63 (Cry2A*), with a relatively higher Bt protein expression in the late growth stage, had an inferior adaptation to nitrogen deficiency compared to its non-Bt counterpart. And this inferior adaptation was found to be correlated with the higher BTC/SPC in MH63 (Cry2A*) leaves in the late growth stage.     

Size of genetic bottlenecks leading to virus fitness loss is determined by mean initial population fitness.

Genetic bottlenecks are important events in the genetic diversification of organisms and colonization of new ecological niches. Repeated bottlenecking of RNA viruses often leads to fitness losses due to the operation of Muller's ratchet. Herein we use vesicular stomatitis virus to determine the transmission population size which leads to fitness decreases of virus populations. Remarkably, the effective size of a genetic bottleneck associated with fitness loss is greater when the fitness of the parental population increases. For example, for starting virus populations with low fitness, population transfers of five-clone-to-five-clone passages resulted in a fitness increase. However, when a parental population with high fitness was transferred, 30-clone-to-30-clone passages were required simply to maintain fitness values.     

Extreme fitness differences in mammalian and insect hosts after continuous replication of vesicular stomatitis virus in sandfly cells.

Continuous, persistent replication of a wild-type strain of vesicular stomatitis virus in cultured sandfly cells for 10 months profoundly decreased virus replicative fitness in mammalian cells and greatly increased fitness in sandfly cells. After persistent infection of sandfly cells, fitness was over 2,000,000-fold greater than that in mammalian cells, indicating extreme selective differences in the environmental conditions provided by insect and mammalian cells. The sandfly-adapted virus also showed extremely low fitness in mouse brain cells (comparable to that in mammalian cell cultures). It also showed an attenuated phenotype, requiring a nearly millionfold higher intracranial dose than that of its parent clone to kill mice. A single passage of this adapted virus in BHK-21 cells at 37 degrees C restored fitness to near neutrality and also restored mouse neurovirulence. These results clearly illustrate the enormous capacity of RNA viruses to adapt to changing selective environments.     

Hydrogel substrate amendment alleviates drought effects on young citrus plants

Water deficits affect citrus physiology, yield, fruit size and quality. Citrus can respond to drought stress conditions through endogenous hormonal regulation of water status and leaf abscission. In this work, we assayed the efficiency of an amendment to soilless media in delaying the drought stress effect in young citrus seedlings and trees. Substrate amendment promoted plant survival of citrus seedlings subjected to several cycles of drought stress and rehydration. In budded trees, the amendment increased substrate water content, leaf water potential, leaf number, root biomass, CO₂ assimilation and stomatal conductance over that of control plants growing in non-amended substrates. We conclude that the substrate amendment reduced the damaging effects of drought stress in citrus plants. The longer survival of seedlings in the amended treatment together with the reduction in leaf abscission and the improvement of physiological parameters, can account for a higher vigour of citrus grown under water stress conditions.     

Genetic and epigenetic relationship in rye, Secale cereale L., somaclonal variation within somatic embryo-derived plants

In vitro regenerated plants of rye, Secale cereale L., Ailés and Merced cultivars, were studied to verify if genetic and/or epigenetic changes were promoted by in vitro conditions. Inter-simple sequence repeat (ISSR) fingerprints on HpaII/MspI-digested and uncut DNA were generated. DNA digested with methylation-sensitive isoschizomers revealed epigenetic modifications, while modification of ISSR patterns obtained with undigested DNA indicated genetic changes. With this technique, it was possible to study both genetic and/or epigenetic changes within the same DNA sequences. The frequency of plants with at least one variation was high: 73% and 30% of rye plants showed at least one genetic change, and 50% and 73% carried at least one methylation change, in the Ailés and Merced cultivars, respectively. Further analyses revealed that a considerable number of variable markers showed both types of modifications, indicative of both genetic and epigenetic changes. Moreover, genetic variation was related to the presence of the CCGG target in the analyzed bands. These results indicate the possible existence of a common mechanism connecting both types of variation.     

Thermodynamic concepts in the study of microbial populations: age structure in Plasmodium falciparum infected red blood cells

Variability is a hallmark of microbial systems. On the one hand, microbes are subject to environmental heterogeneity and undergo changeable conditions in their immediate surroundings. On the other hand, microbial populations exhibit high cellular diversity. The relation between microbial diversity and variability of population dynamics is difficult to assess. This connection can be quantitatively studied from a perspective that combines in silico models and thermodynamic methods and interpretations. The infection process of Plasmodium falciparum parasitizing human red blood cells under laboratory cultivation conditions is used to illustrate the potential of Individual-based models in the context of predictive microbiology and parasitology. Experimental data from several in vitro cultures are compared to the outcome of an individual-based model and analysed from a thermodynamic perspective. This approach allows distinguishing between intrinsic and external constraints that give rise to the diversity in the infection forms, and it provides a criterion to quantitatively define transient and stationary regimes in the culture. Increasing the ability of models to discriminate between different states of microbial populations enhances their predictive capability which finally leads to a better the control over culture systems. The strategy here presented is of general application and it can substantially improve modelling of other types of microbial communities.     

Designed and naturalised sward response to management: I. Patterns of herbage production

Pastures in the Appalachian region of the United States comprise a mix of grasses, legumes and forbs that tend to differ in productivity within and among years. A high degree of spatial variability in hill‐land pasture creates microsite conditions that influence botanical composition of pasture. The variation in sward composition presents logistical challenges to livestock producers who rely on a dependable supply of herbage mass and nutritive value to meet production goals. Our objective was to determine if forage communities sown for specific functions, for example, superior dry matter productivity, resource patch exploitation or targeted seasonal production, adapted to changing growing conditions within and among years. Productivity of communities differed among years reflecting the cumulative influences of time, ontogenetic and environmental variations. Maximum productivity was influenced by the specific forage community and less so by simple clipping and fertiliser management. Naturalised swards clipped to emulate hay management tended to have sustained herbage productivity but lower nutritive value when compared to sown communities. Rankings of dry matter productivity of communities were similar for each year where bioactive composition, high productivity and warm season tended to produce the most, and stoloniferous‐rhizomatous and naturalised pasture the least. Regardless of initial sward composition, effective number of species as an index of diversity increased when frequently clipped swards were not fertilised, and when infrequently clipped swards were fertilised. Dry matter production patterns were not influenced by the effective number of species in any forage community suggesting that key species sustained productivity with volunteer species making lesser contribution to total productivity. The species composition of forage plant communities appears to be more important than clipping or fertiliser management practices as a means to sustain forage productivity.