Species delimitation of the northeastern Anatolian Symphytum (Boraginaceae) taxa

Symphytum is regarded one of the most complicated genera in terms of the classification of its members among the Boraginaceae. In addition to different infrageneric classification methods, several species complex or aggregates have been proposed to deal with the taxonomical problem of genus members. Symphytum asperum aggregate was first introduced by Kurtto, who proposed six taxa within this aggregate. However, according to further studies by different researchers based on morphological data, total number of species of the complex was variable. The number of species was reduced to three, comprising S. asperum, S. savvalense, and S. sylvaticum, after the phylogenetic and morphological studies of Tarıkahya-Hacıoğlu and Erik. However, the taxonomical status of some of these species (i.e., S. savvalense and S. sylvaticum, and S. sepulcrale), which was assigned as a member of this complex by Kurtto, has been regarded as unresolved. To solve this uncertainty, different species delimitation methods were used, including statistical parsimony network analysis (TCS), generalized mixed Yule coalescent (GMYC), and Bayesian Phylogenetics and Phylogeography (BPP) of the ITS, trnL-F and trnS-G sequence data. In addition to members of this complex, S. ibericum, which is phylogenetically nested within the S. asperum aggregate, was also used. The TCS and GMYC analyses demonstrated more complicated clusters, whereas high posterior probabilities of BPP clusters were more compatible with the morphological data. In accordance with the morphological approach of Tarıkahya-Hacıoğlu and Erik, the species delimitation analyses based on molecular data support the recognition of S. asperum, S. ibericum, S. savvalense, and S. sylvaticum as different species.

Introducing improvements in the mass rearing of the housefly: biological, morphometric and genetic characterization of laboratory strains

Understanding the biology of the housefly (Musca domestica L.) is crucial for the development of mass-rearing protocols in order to use this insect as a degradation agent for livestock waste. In this study, the biological and genetic differences between different laboratory strains of M. domestica were analysed. Additionally, hybrids were obtained by mixing the strains and their biological parameters were also measured. The three strains of M. domestica presented differences in their biological and morphological parameters, the main differences were: size, egg production and developmental time. The strain A (specimens from Central Europe) had the best qualities to be used in mass-rearing conditions: it produced the largest quantities of eggs (5.77±0.38 eggs per female per day), the individuals were larger (12.62±0.22 mg) and its developmental time was shorter (15.22±0.21 days). However, the strain C (specimens from SW Europe) produced the fewest eggs (3.15±0.42 eggs per female per day) and needed 18.16±0.49 days to develop from larva to adult, whilst the females from strain B (from South America) produced 4.25±0.47 eggs per day and needed 17.11±0.36 days to complete its development. Genetic analysis of the original laboratory strains showed four different mtDNA cytochrome c oxidase subunit I haplotypes. Statistical parsimony network analysis showed that the SW Europe and South-American strains shared haplotypes, whereas the Central Europe strain did not. Upon hybridizing the strains, variations in egg production and in developmental time were observed in between hybrids and pure strains, and when mixing Central European and South-American strains only males were obtained.

A study on the phylogeny and phylogeography of a marine cosmopolite diatom from the southern Black Sea

A single-cell PCR method was applied to Pseudo-nitzschia pungens strains from the southern Black Sea. Based on the aligment set of the LSU D1-D3 region, a Bayesian molecular phylogeny analysis and a parsimony network analysis were used to investigate phylogenetic clades (Clades I-III) in P. pungens and to determine the ancestral clades. The parsimony network analysis also demonstrated that ancestral haplotypes belonged to Clade II, residing around the northeastern Pacific, while Clade I was distributed globally but antitropicaly. According to the findings of this study, the Black Sea strain (Clade III) shows a global phylogeographic pattern.