Through consulting the ancient herbs and medical books,combining with modern literature and field investigation,this paper makes textual research on herbal medicine,and makes textual research on the name,origin,position and changes of collection and processing of the medicinal herbs in Ancient Classical Prescriptions. " Zhu" wasn't distinguished before the Northern and Southern Dynasties,but the efficacy of the techniques recorded in the documents at that time was similar to that of today's Atractylodis Rhizoma.Tao Hongjing put forward the theory of " red and white" in the Northern and Southern Dynasties. " Cangzhu" and " Baizhu" gradually differentiated,but there was no clear distinction between them. Since Song and Yuan Dynasties, " Baizhu" has been respected and classified in the literature. In Ming Dynasty, " Baizhu" was cultivated and differentiated into different quality specifications according to its growth pattern and origin. Maoshan is the genuine production area of " Cangzhu". The quality of wild " Baizhu" produced in Yuqian city is the best. In modern times,the origins of " Cangzhu" and " Baizhu" were defined according to plant taxonomy. " Zhu" before Song Dynasty was close to Atractylodes lancea, " Baishu" had been respected since the Song Dynasty. So when Song people revised the previous literature,they unified " Zhu" into " Baizhu" and used it for later generations. Its safety and effectiveness have been confirmed,and the wild resources of modern atractylodes are scarce. Therefore,it is suggested that when classical famous prescriptions are developed,the prescription recorded as " Baizhu" does not need to be changed in its origin,that is,A. macrocephala at present or can choose the appropriate basis according to the principle of local righteousness.Textual research shows that the origin of " Cangzhu" in the classical prescription should be A. lancea.
Atractylodes/classification* ; China ; Drugs, Chinese Herbal ; Medicine, Chinese Traditional ; Phytotherapy ; Plants, Medicinal/classification* ; Rhizome

The phylogenetic relationships of the genus Atractylodes DC. was analyzed using the nuclear ribosomal ITS and three chloroplast fragments, including atpB-rbcL, psbB-psbF and trnL-trnF intergenic spacer (IGS) sequences. Phylogenetic analyses revealed that A. lancea subsp. luotianensis and A. lancea, A. chinensis var. liaotungensis and A. coreana form monophyletic terminal clade, separately. The trees, within each the pairwise genetic distances, did not support Hu's classification. Authors suggested that A. lancea Subsp. luotianensis should be included in A. lancea rather than be treated as a separate subspecies. A. carlinoides was placed in the basal position of Atractylodes, which had a distant relationship with the others of the genus. The results lead us to suggest that A. chinensis var. liaotungensis be put into A. coreana, A. chinensis as a subspecies of A. lancea.
Atractylodes ; classification ; genetics ; DNA, Intergenic ; genetics ; DNA, Plant ; genetics ; Genes, Plant ; Phylogeny

OBJECTIVETo assess the genetic diversity of Atractylodes macrocephala in 12 cultivated populations and 3 wild populations.

METHODThe molecular marker technique ISSR was used to investigate the genetic diversity of 365 samples from 15 populations in Zhejiang, Anhui and Hebei Provinces. Data was analyzed by POPGEN 32, and a cluster diagram was presented by UPGMA.

RESULTOne hundred and two amplified fragments were obtained using 13 ISSR primers. 94 polymorphic loci were identified as 92.16%. Nei's genetic diversity index (He) was 0.406 5, Shannon diversity index (I) was 0.590 3, and the coefficient of gene differentiation (Gst) was 0.202 5. The genetic similarity coefficient among the populations ranged from 0.690 7 to 0.960 5 in an average of 0. 825 6. No significant difference was found among the populations based on the clustering analysis.

CONCLUSIONThere is a low level of genetic differentiation in higher genetic diversity of the A. macrocephala populations. No obvious regional or species diversities were identified. This is consistent with current status of cultivation and gerplasm circulation in A. macrocephala.

OBJECTIVETo investigate the genetic diversity of main germplasm of Atractylodes macrocephala in China and the genetic differentiation of the germplasm of A. macrocephala.

METHODA molecular marker ISSR was used to analyze the genetic diversity of 7 populations of A. macrocephala and a population of A. lancea.

RESULTTwelve primers were used in the PCR amplification of 86 samples of A. macrocephala and 5 samples of A. lancea. Sixty-three bands with sizes ranged from 100 to 2500 bp were generated from 12 primers. Of all the 63 bands, 55 bands were polymorphic among 86 individuals of A. macrocephala, the percentage of polymorphic bands were 87.30% at the species level. The percentage of polymorphic bands (PPL) for a single population ranged from 58.73% to 71.43% (mean, 64.85%). Among the 7 populations, a population from Panan, GM exhibited highest variability (PPL =71.43%; HE = 0.2835; I = 0.4267). A dendrogram constructed by an unweighted pair group method of cluster analysis showed that populations from Panan constructed one branch and separated from other populations. In the AMOVA analysis, low level of genetic differentiation among populations was detected, 90.52% of the variability existed in population.

CONCLUSIONThe genetic diversity of cultivated A. macrocephala in China is high, which is good for the production of high quality herb medicine.

In this paper,the structures, data sources, data codes of "the spacial analysis database of geoherbs" based 3S technology are introduced, and the essential functions of the database, such as data management, remote sensing, spacial interpolation, spacial statistics, spacial analysis and developing are described. At last, two examples for database usage are given, the one is classification and calculating of NDVI index of remote sensing image in geoherbal area of Atractylodes lancea, the other one is adaptation analysis of A. lancea. These indicate that "the spacial analysis database of geoherbs" has bright prospect in spacial analysis of geoherbs.
Atractylodes ; chemistry ; classification ; growth & development ; China ; Databases, Factual ; Ecosystem ; Geographic Information Systems ; Geography ; Plants, Medicinal ; chemistry ; classification ; growth & development ; Software

Single nucleotide polymorphisms (SNP) is an important molecular marker in traditional Chinese medicine research, and it is widely used in TCM authentication. The present study created a new genotyping method by combining restriction endonuclease digesting with melting curve analysis, which is a stable, rapid and easy doing SNP genotyping method. The new method analyzed SNP genotyping of two chloroplast SNP which was located in or out of the endonuclease recognition site, the results showed that when attaching a 14 bp GC-clamp (cggcgggagggcgg) to 5' end of the primer and selecting suited endonuclease to digest the amplification products, the melting curve of Lonicera japonica and Atractylodes macrocephala were all of double peaks and the adulterants Shan-yin-hua and A. lancea were of single peaks. The results indicated that the method had good stability and reproducibility for identifying authentic medicines from its adulterants. It is a potential SNP genotyping method and named restriction endonuclease digest - melting curve analysis.
Atractylodes ; classification ; genetics ; DNA Restriction Enzymes ; metabolism ; DNA, Plant ; genetics ; Drug Contamination ; Genotype ; Lonicera ; classification ; genetics ; Plants, Medicinal ; classification ; genetics ; Polymorphism, Single Nucleotide

In order to transform main active ingredient of volatile oil, endophytic fungi were screened from the root of Atractylodes lancea. Transformation method was used in vitro. The changes of volatile oil were traced by gas chromatography. One endophytic fungus (strain ALG-13) which could uitilize volatile oil selectively was screened. Single factor experiment were conducted for exploring the effects of various factors that including kinds of carbon source, speed, liquid volume, pH and concentration of plant tissue on degradation by this strain. Subsequently, the main affecting factors carbon source, speed, pH and liquid volume were optimized using orthogonal array design. Results showed that endophytic fungus ALG-13 selectively used the volatile oil, change the relative percentage of the main components of volatile oil, Atractylon and Atractydin were increased, While, beta-eudesmol and Atractylol decreased. After selectively degradation by fungus, volatile oil components percentage were closer to the geo-herbs. Strain ALG-13 was identified as Bionectria ochroleuca according to its morphological characteristics and systematic analysis of ITS sequence. The optimal conditions were as follows: sucrose used as carbon source, rotating speed was 200 r x min(-1), initial pH for medium was 4.5, 50 mL liquid was added in 250 mL flask. The endophytic fungus ALG-13 could degrade the volatile oil selectively, which was benefit for forming geoherbs A. lancea volatile oil composition.
Atractylodes ; chemistry ; microbiology ; Fungi ; classification ; genetics ; isolation & purification ; metabolism ; Oils, Volatile ; chemistry ; metabolism ; Phylogeny ; RNA, Ribosomal, 18S ; genetics

In this study， an endophytic bacteria strain BZJN1 was isolated from Atractylodes macrocephala， and identified as Bacillus subtilis by physiological and biochemical tests and molecular identification. Strain BZJN1 could inhibit the growth of mycelia of Ceratobasidium sp. significantly， and the inhibition rate was more than 70%. The mycelium growth deformity with bulge as spherical and partially exhaustible in apex or central with microscopic observation. The inhibitory rates under 3% and 6% concentrations of the cell free fermentation were 22.7% and 38.7% expectively. The field test proved that the control efficacy of treatment of 1×10⁸ cfu·mL⁻¹ is 75.27% and 72.37% after 10 and 20 days. All the treatments of strain BZJN1 was able to promote the growth of A. macrocephala， the treatment of 1×10⁸ cfu·mL⁻¹ could able to increase the yield to 14.1%.
Atractylodes ; microbiology ; Bacillus subtilis ; physiology ; Basidiomycota ; pathogenicity ; Biological Control Agents ; Endophytes ; classification ; isolation & purification ; Plant Diseases ; microbiology ; prevention & control

To identity the pathogen that causes the mosaic and yellowing symptoms on Atractylodes macrocephala Koidz in Jiangxian, Shanxi province, biological inoculation, sequence-independent amplification (SIA),RT-PCR and other identification methods were used. The results showed that the chlorotic and necrosis symptoms occurred in the indicator plant Chenopodium quinoa after it was infected with the pathogen,and the same symptoms appeared after the reinoculation of healthy Atractylodes macrocephala Koidz; this reflected that the disease was likely to be caused by a virus. The results of SIA and sequencing showed that Broad bean wilt virus 2 (BBWV2) was present in severely mosaic Atractylodes macrocephala Koidz leaves. To further characterize the BBWV2 isolate from Atractylodes macrocephala (BBWV2-Am), the polyprotein partial gene encoded by BBWV2-Am RNA2 was cloned and sequenced. Sequence alignments showed that the nucleotide sequence identity of BBWV2-Am SCP and LCP genes ranged from 79.3% to 87.2% and from 80.1% to 89.2% compared to other BBWV2 strains,respectively; the deduced amino acid sequence similarities of the two gene products ranged from 91.2% to 95.7% and from 89.44 to 95.5%, respectively,compared to those of other BBWV2 strains. Phylogenetic comparisons showed that BBWV2-Am was most likely to be related to BBWV2-Rg,but formed an independent branch. This is the first report of BBWV2 in Atractylodes macrocephala Koidz.
Amino Acid Sequence ; Atractylodes ; virology ; Fabavirus ; chemistry ; classification ; genetics ; isolation & purification ; Molecular Sequence Data ; Phylogeny ; Plant Diseases ; virology ; Sequence Analysis ; Viral Proteins ; chemistry ; genetics

Atractylodis Macrocephalae Rhizoma and Atractylodis Rhizoma were widely used in strengthening spleen under different disease conditions, and were easily and often misused each other. Therefore, DNA barcode was used to distinguish Atractylodis Macrocephalae Rhizoma and Atractylodis Rhizoma from their adulterants to ensure the safe use. The sequence lengths of ITS2 of Atractylodes macrocephala, Atractylodis Rhizoma (A. lancea, A. japonica and A. coreana) were both 229 bp. Among the ITS2 sequences of A. macrocephala, only one G/C transversion was detected at site 98, and the average GC content was 69.42%. No variable site was detected in the ITS2 sequences of A. lancea. The maximum K2P intraspecific genetic distances of both A. japonica and A. coreana were 0.013. The maximum K2P intraspecific genetic distances of A. macrocephala, A. lancea, A. japonica and A. coreana were less than the minimum interspecific genetic distance of adulterants. The ITS2 sequences in each of these polytypic species were separated into pairs of divergent clusters in the NJ tree. DNA barcoding could be used as a fast and accurate identification method to distinguish Atractylodis Macrocephalae Rhizoma, Atractylodis Rhizoma, from their adulterants to ensure its safe use.
Atractylodes ; classification ; genetics ; DNA Barcoding, Taxonomic ; methods ; DNA, Plant ; genetics ; DNA, Ribosomal Spacer ; genetics ; Drug Contamination ; prevention & control ; Drugs, Chinese Herbal ; chemistry ; classification ; Molecular Sequence Data ; Phylogeny ; Quality Control ; Rhizome ; classification ; genetics