Is the bryophyte soil diaspore bank buffered against nutrient enrichment and grazing exclusion?

Plant and Soil - Soil diaspore banks of bryophytes are poorly known in tundra grasslands, yet can be important for the maintenance of local bryophyte assemblages. We examined the effects of...     

Can a seed bank maintain the genetic variation in the above ground plant population?

There are indications that a persistent seed bank can protect small and isolated plant populations from local extinction. Genetic mechanisms contributing to this phenomenon are the increase of local effective population size – and hence the decrease of genetic drift – through a reservoir of persistent seeds, and the accumulation of intergenerational genetic diversity in the seed bank. To find evidence for these mechanisms, we conducted two formal meta-analyses. First, we analyzed 42 published habitat fragmentation studies and investigated whether the degree of genetic differentiation between fragmented plant populations was mediated by seed longevity. Second, we reviewed 13 published studies reporting the genetic diversity of both the seed bank and the above ground plants, aiming at comparing genetic diversity contained in the seed bank with the above ground vegetation. We conclude that a persistent seed bank may indeed mitigate the consequences of habitat fragmentation and protect a species from genetic drift and population genetic differentiation. We found no evidence, however, of high levels of genetic diversity accumulating in the soil seed bank. If genetic differences are present between the standing crop and the seed bank, they are very likely the result of local selection acting either directly or indirectly as a filter on the alleles present in the seed bank. We finally suggest that 1) the role of the seed bank should not be neglected in habitat fragmentation studies and 2) it is not very fruitful to continue comparing seed bank genetic diversity with above ground plant genetic diversity, unless this is performed under different selection regimes.     

How much genetic variation is stored in the seed bank? A study of Atriplex tatarica (Chenopodiaceae)

We investigated to what extent the soil seed bank differed genetically and spatially in comparison to three consecutive life history stages (seedlings, mature plants, and fruiting plants) in a natural population of Atriplex tatarica. Representatives of particular life history stages from twenty subunits within a large population were randomly collected and subjected to allozyme analysis. Comparison of population polymorphism among various life history stages showed significant differences in observed heterozygosity (H(O)) and F statistics (F(IS) and F(ST)), but nonsignificant ones in the cases of number of alleles per polymorphic locus (A) and gene diversity (H(S)). These results indicate an increasing number of heterozygotes, a decreasing level of inbreeding and an increase of the partitioning genetic diversity among populations with increasing population age. Spatial autocorrelation was used to calculate f, the average co-ancestry coefficient between individuals within distance intervals of two meters along a 39 m long transect. Significant positive fine scale genetic structure was detected in mature and fruiting plants but not in soil seeds and seedlings stages. The results of the presented study on A. tatarica indicated that significant differences exist in genetic differentiation, differentiation in allele frequencies and spatial autocorrelation among early (soil seeds and seedlings) and late (mature and fruiting plants) life history stages but not within early and late ones. This pattern suggests that, rather than storing genetic variability in the soil or germination and establishment success, self-thinning might be the major microselective force in populations of A. tatarica.     

Postglacial range expansion and its genetic imprints in Abies alba (Mill.) — A synthesis from palaeobotanic and genetic data

We present a range-wide synthesis of our own research and related work on the complex postglacial history of Abies alba Mill. It is based on macroremains, fossil pollen records as well as on different genetic markers. The geographic distribution of genetic lineages and allele frequencies together with the fossil records confirm multiple refugia with at least three of them being sources for the Holocene range expansion into Central Europe, representing so-called effective refugia. One is located in the northern Apennines. A long-term refugium in the southern Balkans contributes to northward expansion with a branch along the Carpathians in the East and the Dinaric Alps in the West. Furthermore, new allozyme data indicate a third effective refugium in the northern or western Balkans, respectively. Using different genetic marker categories the differentiation of A. alba populations could be attributed to different time scales. A separation of maternal lineages took place in previous glacial cycles of the Quaternary, while a second pattern of genetic differentiation is the result of isolation processes during the last glaciation and subsequent gene flow after range expansion. Suture and introgression zones of refugial gene pools were clearly recognised. The patterns of genetic variation and genetic diversity spanning between rear and leading edges of the present range are discussed for evolutionary implications and conservation strategies.     

Codon–anticodon interaction and the genetic code evolution

The evolution of the genetic code, with 20 amino acids encoded from the beginning, is analyzed from the viewpoint of codon–anticodon interaction. Imposing a minimum principle for the interaction, in the framework of the so called crystal basis model of the genetic code, we determine the structure of the anticodons in the ancient, archetypal and early genetic codes, that are all reconciled in a unique frame. Most of our results agree with the generally accepted scheme.     

Two genetic stocks of Steindachneridion melanodermatum living in sympatry in nature and genetic variability of wild parents and F₁ generation

Steindachneridion melanodermatum is a large Brazilian catfish, highly prized for sport fishing and for its meat. Specimens of this species, both caught in nature from Iguacu River and F(1) fish born in captivity, were analyzed with regard to patterns of RAPD molecular markers. Genetic similarity ranged from 0.57 to 0.95; two groups were determined for the wild specimens. The results suggest different genetic lineages in sympatry in nature. Heterozygosity and percentage of polymorphic loci were 0.31 and 79% and 0.23 and 62%, respectively, for the two populations of wild specimens and 0.26 and 66%, respectively, for those born in captivity.     

Indirect genetic effects and the lek paradox: inter-genotypic competition may strengthen genotype × environment interactions and conserve genetic variance

Understanding the evolutionary mechanisms that maintain genetic variation in natural populations is one of the fundamental goals of evolutionary biology. There is growing evidence that genotype-by-environment interaction (G × E) can maintain additive genetic variance (V _A), but we lack information on the relative performance of genotypes under the competitive situations encountered in the field. Competing genotypes may influence each other, and this interaction is also subject to selection through indirect genetic effects (IGE). Here, we explore how genotypes perform when interacting and evaluate IGE in order to understand its influence on V _A for sexually-selected traits in the lesser waxmoth, Achroia grisella. We found that inter-genotype differences and crossover interactions under joint rearing are equal to or greater than values when reared separately. A focal genotype exhibited different performances when jointly reared with various genotypes—suggesting that IGE may be responsible for the increased levels of crossover and differences in performance observed. We suggest that some genotypes are superior competitors for food acquisition in the larval stage, and that these differences influence the development and evolution of other genotypes through IGE. We reaffirm the role of G × E in maintaining V _A and note the general importance of IGE in studies of evolutionary mechanisms.     

Agyria — pachygyria and Miller-Dieker syndrome: clinical,genetic and chromosome studies

Summary Twelve cases of lissencephaly are reported. A high resolution chromosome study was performed on each in order to detect small chromosomal anomalies, undetectable with routine techniques. Only one case was shown to have an unbalanced karyotype with a microdeletion of the short arm of chromosome 17(del 17p). This child also had symptoms of the Miller-Dieker syndrome, consisting of lissencephaly, characteristic facies, pre- and post-natal growth retardation and other birth defects. As proposed by Dobyns, it seems justifiable to classify lissencephalies into four different groups, according to other clinical manifestations and results of chromosome studies.     

Plasma norepinephrine and dopamine-β-hydroxylase in genetic hypertensive rats

The relationship between blood pressure, plasma norepinephrine (NE), dopamine-β-hydroxylase (DBH) activity and age was investigated in spontaneously hypertensive rat (SHR), a stroke-prone substrain of the SHR and control Wistar-Kyoto rat (WKR). Blood pressure of both SHR strains increased with age and was significantly higher than that of the WKR at all ages tested (3 15 weeks). The blood pressure of stroke-prone SHR was significantly higher than that of the regular SHR after 6 weeks of age. Plasma DBH activity decreased with age in each strain, although the SHR, and especially the stroke-prone SHR, had significantly higher DBH than the controls at an early age. Plasma NE in the WKR did not change with age. Increased plasma NE was observed only in the young SHRs. The highest values were found in the 6 week old stroke-prone SHR. These data suggest that plasma DBH activity is not correlated directly with plasma NE or blood pressure, but that increased sympathetic nerve activity may occur during the development of hypertension in the SHR and the stroke-prone SHR.     

Dy and Nd induced genetic mutation of bacillus α-amylase

After treatment with DyCl₃ and NdCl₃, two strains of mutated bacilli showing increased α-amylase activity were isolated. The α-amylase genes were amplified, cloned, and sequenced. Sequencing revealed that there were either 11 or 14 bases altered in the two genes. These alterations took the form of base substitutions, and transversion was more common than transition. Based on these results, it was concluded that the rare earth compounds DyCl₃ and NdCl₃ were mutagens.     

Insurance and genetic testing: where are we now?

Basic research will spur development of genetic tests that are capable of presymptomatic prediction of disease, disability, and premature death in presently asymptomatic individuals. Concerns have been expressed about potential harms related to the use of genetic test results, especially loss of confidentiality, eugenics, and discrimination. Existing laws and administrative policies may not be sufficient to assure that genetic information is used fairly. To provide factual information and conceptual principles upon which sound social policy can be based, the Human Genome Initiative established an Ethical, Legal, and Social Issues Program. Among the first areas to be identified as a priority for study was insurance. This paper provides a review of life, health, and disability insurance systems, including basic principles, risk classification, and market and regulatory issues, and examines the potential impact of genetic information on the insurance industry.     

Does habitat fragmentation reduce genetic diversity and subpopulation connectivity?

The estimation of levels of genetic variation has received considerable attention because it is generally thought to be indicative of overall species vitality and the potential for evolutionary responses to environmental changes. Here, we use allozymes markers and two distinct collections of Cakile maritima, an annual species from sandy coastal habitats (2000 generation and 2005 generation collected from 9 populations in their natural habitats), to assess the magnitude of expected genetic change. We compared genetic diversity between generations (all populations combined), and then between populations at each generation. Based on 13 loci scored from the eight enzymes examined, a high genetic diversity was detected at both the population and generation level as compared to other herbaceous species. However, allelic richness reduction in the 2005 generation suggested restricted gene flow and a high risk of future genetic bottlenecks, if larger tracts of coastal areas disappear. Most loci showed deviation from Hardy‐Weinberg equilibrium due to excess of heterozygotes in all populations suggesting that this species has an allogamic mode of reproduction. It appears most likely that this species has experienced a recent decrease in population size, and that genetic drift in small populations has resulted in a loss of alleles occurring at low frequency. Despite the deterioration process, maintenance of high genetic diversity suggests that there are some ecological factors determining population structure.     

Scale-specific determinants of a mixed beech and oak seedling–sapling bank under different environmental and biotic conditions

Based on the hypothesis that both plant size and local conspecific density influence allocation to female/male functions, we explored the relationship between plant height, local conspecific density, sexual expression, and fruit production in the andromonoecious shrub Caesalpinia gilliesii. We quantified the total number of perfect and staminate flowers, the pollen received and fruits produced per plant in two populations, and estimated phenotypic gender and fruit set. Local density failed to explain phenotypic gender, nevertheless, plant height and fruit set increased with local density in one population where, in addition, the slopes for the size-dependent sex allocation curve were steeper. As observed for other plant species, this suggests that between population differences in resource availability is the main underlying factor for the observed population differences in the size-dependent allocation pattern to flowers and fruits. On the other hand, the number of staminate and perfect flowers per plant increased with plant height and the fastest increase of staminate flowers resulted in a male-biased size-dependent sex allocation strategy in both populations. Since pollination intensity was not correlated with plant height in any population, the observed allocation strategy cannot be attributed to differences in pollen availability between different sized individuals, but to differences in plant size. Finally, because fruit set and total fruit number increased with plant height in one population, the obtained results provide further evidence that animal-pollinated, andromonoecious species may exhibit a male-biased size-dependent sex allocation strategy, which may favor female fecundity.     

Microbial acid-stable α-amylases: Characteristics,genetic engineering and applications

Among the wide variety of amylolytic enzymes synthesized by microorganisms, α-amylases are the most widely used biocatalysts in starch saccharification, baking industries and textile desizing. These enzymes randomly cleave the α-1,4-glycosidic linkages in starch, generating maltose and malto-oligosaccharides. The commercially available α-amylases have certain limitations, such as limited activity at low pH and Ca²⁺-dependence, and therefore, the search for novel acid-stable and thermostable amylases from extremophilic microorganisms and the engineering of the already available enzymes have been the major areas of research in this field over the years. Several attempts have been made to find suitable microbial sources of acid-stable and thermostable α-amylases. Acid-stable α-amylases have been reported in fungi, bacteria and archaea. α-Amylases that are active at elevated temperatures have been reported in bacteria as well as in archaea. α-Amylases that possess both characteristics, to the extent required for their various applications are very scarce. The developments that have been made in molecular biology, directed evolution and structural conformation studies of α-amylases for improving their properties to suit various industrial applications are discussed in this review.     

β-Turn-driven early evolution: The genetic code and biosynthesis pathways

Summary The physicochemical properties of -turns suggest their biological importance prior to the formation of the genetic code. These properties include ones potentially affecting the preference for eitherl- ord-amino acids. The abundance of certain amino acids in -turns is correlated with their assignment to a small, well-defined part of the genetic code and with their role as metabolic precursors for other amino acids. It is proposed that in the prebiotic environment, -turns became objects of selection that influenced the evolution of the genetic code and biosynthetic pathways for amino acids.     

Current applications of wheat and wheat–alien precise genetic stocks

A comprehensive collection of wheat aneuploids, whole chromosome substitutions (both intervarietal and interspecific) and wheat–alien addition lines, along with various introgression and near-isogenic lines, has been created over a period of years, primarily to provide the means of localizing the genes underpinning traits and to introduce novel genes into the bread wheat genome. For a time, interest in this class of genetic material was on the wane, but more recently it has revived in the context, for example, of localizing DNA-based markers, designing chromosome-specific bacterial artificial chromosome libraries, and establishing functional differences between alleles and homoeoalleles. Here, a brief review is provided of recent applications of precise genetic stocks in the field of molecular genetics, functional genetics and genomics of the Triticeae species.