ABSTRACT
Objective:To identify 24 <italic>Rana</italic> species such as <italic>Rana dybowskii</italic> by mitochondrial cytochrome C oxidase subunit I (<italic>CO</italic>Ⅰ) gene-based DNA barcoding and build the neighbour-joining (NJ) tree for hierarchical cluster analysis, so as to provide a basis for the identification and classification of <italic>Rana</italic> species as well as the discovery of new species. Method:<italic>R. dybowskii</italic>, <italic>R. chensinensis</italic>, <italic>R. amurensis</italic>, <italic>R. culaiensi</italic>s, and <italic>R. huanrenesis</italic>, ten for each species, were collected for DNA extraction and polymerase chain reaction (PCR) amplification<italic> </italic>and sequencing. A total of 50 <italic>CO</italic>Ⅰ gene sequences were obtained. Then 163 <italic>CO</italic>Ⅰ gene sequences for 24 species of <italic>Rana</italic> and one <italic>CO</italic>Ⅰ gene sequence for <italic>Pelophylax</italic>,<italic> Odorrana</italic>, <italic>Nidirana</italic>, <italic>Hylarana</italic>, and <italic>Amolops</italic> were harvested from GenBank. After sequence alignment by MEGA X, the parsimony-informative sites of <italic>CO</italic>Ⅰ gene sequences were analyzed and the intraspecific and interspecific genetic distances were calculated, followed by the built of NJ tree and hierarchical cluster analysis. Result:The <italic>CO</italic>Ⅰ gene sequences of 24<italic> Rana</italic> species including <italic>R. dybowskii</italic> were 554 bp in length and there were 210 parsimony-informative sites in total. The intraspecific genetic distance of each species was smaller than 2%. Except that the interspecific genetic distance between <italic>R. sangzhiensis</italic> and <italic>R. zhengi</italic> was 0.004, the genetic distances between the other species ranged from 0.024 to 0.228. <italic>R. sangzhiensis</italic> and <italic>R. zhengi</italic> were clustered into one branch and some <italic>R. dybowskii</italic> and <italic>R. uenoi</italic> into one branch. There were two separate branches for <italic>R. chensinensis</italic> and the other species were all clustered independently. Conclusion:<italic>CO</italic>Ⅰ-based DNA barcoding enabled the identification of 24 species of <italic>Rana</italic> including <italic>R.dybowskii</italic>. The findings supported that <italic>R. sangzhiensis</italic>, <italic>R. zhengi</italic>, <italic>R. coreana</italic>, and <italic>R. kunyuensis</italic> were the same species. One branch of <italic>R. chensinensis </italic>might be one of the four undownloaded species in Ranidae or a new species. The results have demonstrated that <italic>CO</italic>Ⅰ-based DNA barcoding allows not only the identification of 24 species of Rana including <italic>R. dybowskii </italic>but also the classification of ranidae species and the discovery of new species or subspecies.
ABSTRACT
Objective To investigate the densities and species of acaroid mites in stored products in farmer home storages. Methods The mite samples which were collected from the farmers’home in Linquan County, Anhui Province included grains, foods, condiments, fruits and vegetables, and the breeding mites were isolated, then identified and classified after using the mites to make slide specimens. Results Twenty-one species of acaroid mites were obtained, belonging to 7 families and 15 genera. The highest breeding density was in the millet (3 888.89 mite/g) and the lowest was in the fennel (2.03 mite/g), and the frequent breeding species of storages were Tyrophagus putrescentiae and Lepidoglyphus destructor. The average breeding density of acaroid mites in grains was 383.94 mite/g, and the dominant mite species was T. longior. The average breeding density of acaroid mites in condiments was 149.53 mite/g, and the dominant mite species were L. destructor and Chortoglyphus arcuatus. The average breeding density of acaroid mites in foods was 85.15 mite/g, and the dominant mite species were T. putrescentiae, T. longior, T. palmarum, Glycyphagus domesticus and Dermatophagoides farina. The average breeding density of acaroid mites in fruits and vegetables was 49.15 mite/g, and the dominant mite species were Rhizoglyphus robini and T. palmarum. The average breeding density of acaroid mites in other stored products was 25.05 mite/g, and the dominant mite species were T. putrescentiae and L. destructor. Conclusion The species of acaroid mites in home storages are very rich, and it is necessary to take positive measures to reduce the infestation of acaroid mites.
ABSTRACT
Objective To investigate the species and diversity of acaroid mites community in home storages in Linquan ar-ea,Anhui Province.Methods The samples of 48 kinds of storages from the residents in Linquan County were collected,and the mites in them were separated in a microscope directly.Results Totally 19 species of acaroid mites belonging to 14 genera of 6 families were obtained from the 48 kinds of samples.The diversity analysis showed that the number of species,the species richness index and species diversity index of mites in the habitats were in the order of the other storages>drysaltery>grains.Conclusion The quantities of breeding acaroid mites in storages in Linquan area are much larger,meanwhile the species are also very rich,thus in order to reduce the harm of acaroid mites,we should take active measures to control their breeding.
ABSTRACT
Objective To investigate the densities and species of acaroid mites in stored products in farmer home storages. Methods The mite samples which were collected from the farmers’home in Linquan County, Anhui Province included grains, foods, condiments, fruits and vegetables, and the breeding mites were isolated, then identified and classified after using the mites to make slide specimens. Results Twenty-one species of acaroid mites were obtained, belonging to 7 families and 15 genera. The highest breeding density was in the millet (3 888.89 mite/g) and the lowest was in the fennel (2.03 mite/g), and the frequent breeding species of storages were Tyrophagus putrescentiae and Lepidoglyphus destructor. The average breeding density of acaroid mites in grains was 383.94 mite/g, and the dominant mite species was T. longior. The average breeding density of acaroid mites in condiments was 149.53 mite/g, and the dominant mite species were L. destructor and Chortoglyphus arcuatus. The average breeding density of acaroid mites in foods was 85.15 mite/g, and the dominant mite species were T. putrescentiae, T. longior, T. palmarum, Glycyphagus domesticus and Dermatophagoides farina. The average breeding density of acaroid mites in fruits and vegetables was 49.15 mite/g, and the dominant mite species were Rhizoglyphus robini and T. palmarum. The average breeding density of acaroid mites in other stored products was 25.05 mite/g, and the dominant mite species were T. putrescentiae and L. destructor. Conclusion The species of acaroid mites in home storages are very rich, and it is necessary to take positive measures to reduce the infestation of acaroid mites.