Home  About us  Contact
 

European Subspecies (european + subspecy)

Distribution by Scientific Domains
Life Sciences75%

Selected Abstracts

THE AFRICANIZATION OF HONEYBEES (APIS MELLIFERA L.) OF THE YUCATAN: A STUDY OF A MASSIVE HYBRIDIZATION EVENT ACROSS TIME

EVOLUTION, Issue 7 2002
Kylea E. Clarke
Abstract Until recently, African and European subspecies of the honeybee (Apis mellifera L.) had been geographically separated for around 10,000 years. However, human-assisted introductions have caused the mixing of large populations of African and European subspecies in South and Central America, permitting an unprecedented opportunity to study a large-scale hybridization event using molecular analyses. We obtained reference populations from Europe, Africa, and South America and used these to provide baseline information for a microsatellite and mitochondrial analysis of the process of Africanization of the bees of the Yucatan Peninsula, Mexico. The genetic structure of the Yucatecan population has changed dramatically over time. The pre-Africanized Yucatecan population (1985) comprised bees that were most similar to samples from southeastern Europe and northern and western Europe. Three years after the arrival of Africanized bees (1989), substantial paternal gene flow had occurred from feral Africanized drones into the resident European population, but maternal gene flow from the invading Africanized population into the local population was negligible. However by 1998, there was a radical shift with both African nuclear alleles (65%) and African-derived mitochondria (61%) dominating the genomes of domestic colonies. We suggest that although European mitochondria may eventually be driven to extinction in the feral population, stable introgression of European nuclear alleles has occurred. [source]

Verbreitung und Differenzierung der mitteleuropäischen Unterarten von Buglossoides arvensis (L.) I. M. Johnst. (Boraginaceae),

FEDDES REPERTORIUM, Issue 1-2 2003
A. Clermont
In Mitteleuropa sind zwei Unterarten des Ackersteinsamens (Buglossoidesarvensis subsp. arvensis, B. arvensis subsp. sibthorpiana) verbreitet. Die molekularbiologische Untersuchung der nucleären ITS1-Region von 55 mitteleuropäischen Belegen verdeutlicht die Eigenständigkeit der beiden Sippen. Innerhalb des 238 Basenpaare langen Markers unterscheiden sich die Unterarten durch 15 Substitutionen (6,4 %). Die Ergebnisse lassen den Schluss zu, dass die Unterarten bisher aufgrund ihrer morphologischen Plastizität oft verwechselt und Häufigkeit und Verbreitung der Subspecies sibthorpiana unterschätzt wurden. Morphologisch lassen sich die beiden Unterarten anhand folgender Merkmale unterscheiden: Buglossoides arvensis subsp. arvensis besitzt längliche Keimblätter, eine gerade Gynobasis, einen unverdickten, geraden Pedicellus sowie cremefarbene oder selten leicht rosa gefärbte Blüten. Buglossoides arvensis subsp. sibthorpiana zeichnet sich durch runde Keimblätter, eine zur Fruchtzeit leicht zur Blütenstandsachse geneigte Gynobasis, einen schiefen, verdickten Pedicellus an den unteren Früchten und blaue, rosa oder cremefarben gefärbte Blüten aus. Weiterhin unterscheiden sich die Unterarten in ihren ökologischen Ansprüchen: B. arvensis subsp. arvensis kommt nur als Ackerunkraut vor, B. arvensis subsp. sibthorpiana wächst sowohl auf Ackerstandorten als auch auf Trockenrasen, sandigen Ruderalflächen oder in trockenen, lichten Wäldern. Distribution and differentiation of the Central European subspecies of Buglossoides arvensis (L.) I.M.Johnst. (Boraginaceae) The Corn Gromwell (Buglossoides arvensis) has two Central European subspecies, B. arvensis subsp. arvensis and B. arvensis subsp. sibthorpiana. The ITS1-region of 55 European samples was amplified and sequenced and it yielded a 238 bp fragment, which consistently differed by 15 substitutions between the two subspecies. The results suggest that the two subspecies indeed represent two independent taxa and have been confused mainly because of their morphological plasticity. Because of this confusion, distribution and abundance were poorly understood. The subspecies as here re-defined can be distinguished as follows: B. arvensis subsp. arvensis has oblong cotyledons, a horizontal gynobase, an unthickened pedicel in fruit, and a cream-coloured corolla. B. arvensis subsp. sibthorpiana has circular cotyledons, an oblique gynobase, an obliquely thickened pedicel in fruit, and a light blue to (more rarely) cream-coloured corolla. The two taxa show some degree of ecological differentiation: B. arvensis subsp. arvensis is only found as a weed in winter cereals, whereas B. arvensis subsp. sibthorpiana is occasionally found as a weed in fields, but also on dry grasslands, sandy waste sites and road sides, and in dry, open forests. [source]

Retrospective growth analysis of Atlantic salmon Salmo salar and implications for abundance trends

JOURNAL OF FISH BIOLOGY, Issue 10 2010
F. Hogan
Scale archives of Atlantic salmon Salmo salar from Maine, U.S.A., were examined to determine whether ocean conditions affected the long-term trends in S. salar populations in the southern tier of the species' range in North America. To date, scale analyses of southern tier populations have been limited to hatchery fish; previous studies suggest that post-smolt growth does not influence recruitment, with the exception that winter growth may play a role in stock maturation rate. A time series of scales from the Machias and Narraguagus Rivers spanning the years 1946 to 1999 was analysed. Image analysis was used to measure intercirculi spacing, which provided proxy variables of growth rate. Post-smolt growth increment has increased since the early 1990s, as returns have decreased, suggesting that survival factors act on post-smolts independent of growth. The data support the hypothesis of a decoupling between freshwater size and early marine growth. Growth during the second sea winter was independent of post-smolt growth, suggesting that individuals are capable of significant compensatory growth. Southern tier North American stocks exhibit a similar pattern of independence between growth and survival as observed for northern tier North American stocks. These data support the inference that the recruitment of the North American and European subspecies is governed by fundamentally different mechanisms. [source]

The genetic impact of demographic decline and reintroduction in the wild boar (Sus scrofa): A microsatellite analysis

MOLECULAR ECOLOGY, Issue 3 2003
C. Vernesi
Abstract The reintroduction of wild boar from central Europe after World War II has contributed substantially to the range expansion of this species in Italy, where indiscriminate hunting in earlier times resulted in extreme demographic reduction. However, the genetic impact of such processes is not well-understood. In this study, 105 individuals from Italian and Hungarian wild boar populations were characterized for nine autosomal microsatellite loci. The Hungarian samples, and two central Italian samples from protected areas (parks) where reintroduction is not documented, were assumed to be representative of the genetic composition of the source and the target populations in the reintroduction process, respectively. Animals hunted in the wild in the Florence area of Tuscany (Italy) were then studied to identify the effects of reintroduction. The results we obtained can be summarized as follows: (i) none of the populations analysed shows genetic evidence of demographic decline; (ii) the three parental populations from Italy and Hungary are genetically distinct; however, the low level of divergence appears in conflict with the naming of the Italian and the European subspecies (Sus scrofa majori and Sus scrofa scrofa, respectively); in addition, the Italian groups appear to be as divergent from each other as they are from the Hungarian population; (iii) most of the individuals hunted near Florence are genetically intermediate between the parental groups, suggesting that hybridization has occurred in this area, the average introgression of Hungarian genotypes is 13%, but , 45% of the genetic pool of these individuals can not be directly attributed to any of the parental populations we analysed; (iv) analysis of microsatellite loci, though in a limited number, is an important tool for estimating the genetic effect of reintroduc ion in the wild boar, and therefore for the development of conservation and management strategies for this species. [source]