First Report of Pindo Palm Heart Rot Caused by Ceratocystis paradoxa in China.

On January 12th, 2012, a novel disease with an incidence of 50% was discovered in Pindo palm Butia capitata (Mart.) Becc from the Coconut Grant View Garden (19°33.137' N, 110°47.482' E) located in Wenchang, Hainan Province. Diseased leaflets at the base of the rotted heart leaves had reddish brown lesions; when the infection progressed, the leaves turned yellow and became blighted from the inner to the outer part of the crown. Once the growing point was destroyed, the entire tree ultimately died. Tissues from the edges of lesions from diseased leaflet samples were placed onto potato dextrose agar (PDA) and incubated at 25°C for 3 days. The color of colonies of five isolates obtained turned from white to black in 48 h. The optimum temperature for mycelium growth was from 20 to 30°C, and no growth occurred at temperatures higher than 40°C or lower than 5°C (n = 5). The cylindrical colorless to pale brown conidia were 7.5 to 17.5 µm long × 5.0 to 7.5 µm wide (n = 100); oval black chlamydospores were 12.5 to 22.5 × 7.5 to 15.0 µm (n = 100). The sequence (497 bp) of the internal transcribed spacer (ITS) region of the representative isolate BX3 (China Center for Type Culture Collection No. CCTCC AF2014002) was amplified using primer pair ITS1/ITS4 (GenBank Accession No. KF939052) and shared 99% sequence identity with Ceratocystis paradoxa strain xie331-4 (JQ039332). Based upon these biological characteristics and ITS sequence, this pathogen was identified as C. paradoxa (Dade) C. Moreau (anamorph Thielaviopsis paradoxa (de Seynes) Höhn.) (3). Pathogenicity tests were conducted on 8-cm-long sections of young leaflets excised from a 12-year-old pindo palm tree. One side of the midrib of 10 sections was wounded with a sterilized scalpel at the center and the other side was non-wounded, then a PDA plug (4 to 6 × 4 to 6 mm) from the edge of an actively growing colony of BX3 incubated for 3 days were inoculated onto each wounded or non-wounded site. As controls, plain PDA plugs were placed on wounded and non-wounded spots of another 10 sections following the above procedure. Pathogenicity was tested twice. Each inoculated section was then put into a 9-cm petri dish in which two filter papers (Φ = 9 cm) were placed and 8 ml of sterile water were added to maintain high humidity, and then all dishes were placed in a dark incubator at 25°C. After 5 days, typical symptoms developed only on the wounded points inoculated with mycelium plugs. C. paradoxa was re-isolated from the margins of the expanding lesions. C. paradoxa causing fruit rot of B. capitata was reported in Uruguay (2), but to our knowledge, there are no previous reports of this species in China or infecting leaves of B. capitata worldwide (1). We report here a new Ceratocystis disease on B. capitata, and it was named as pindo palm heart rot based on its symptoms. References: (1) D. F. Farr and A. Y. Rossman. Fungal Databases, Systematic Mycology and Microbiology Laboratory, ARS, USDA. Retrieved from http://nt.ars-grin.gov/fungaldatabases/ , Feb 21, 2014. (2) V. Gepp et al. New Dis. Rep. 27:12, 2013. (3) F. Y. Yu et al. Plant Dis. 96:290, 2012.

First Report of Leaf Spot of Tea Oil Camellia (Camellia oleifera) Caused by Lasiodiplodia theobromae in China.

Tea oil camellia (Camellia oleifera Abel.), one of the most famous woody oil plants, is distributed and cultivated widely in central and southern China for its strong adaptability. In September 2013, tea oil camellia plants with severe leaf spots were observed in commercial production fields located in Wenchang, Hainan Province. Spots were initially chlorotic, became necrotic and black with a chlorotic halo, developing to cover the entire width of the leaves, and leading to leaf death. Isolations were performed by excising pieces of symptomatic leaves from the lesion margin, surface sterilized with 90% ethanol and 0.6% sodium hypochlorite, and then placed them on potato dextrose agar (PDA). Plates were incubated in a sterile chamber at 26 ± 2°C for 2 days. A fungus was consistently isolated on PDA from all 23 diseased leaf samples. Pure cultures were obtained by monosporic culture technique. After 2 to 3 days of incubation at 26 ± 2°C with a 12-h photoperiod, the fungus initially produced white colonies with dense aerial mycelia, which later turned black (6 to 7 days). The mycelium was fast spreading, branched, and septate. Pycnidia were black, globose, ostiolate, and produced in stroma on the medium surface after 28 days at the same culture conditions as above. Conidia were initially unicellular, subovoid, hyaline, thick-walled with granular content, and 19.8 to 28.9 × 11.5 to 15.7 µm (avg. 25.1 × 13.5 µm). Mature conidia were one-septate and dark brown with longitudinal striations. These observed morphological features suggested that the fungus possessed the same characteristics as previously described for Lasiodiplodia theobromae (Pat.) Griffon & Maubl (syn = Botryodiplodia theobromae) (2). For molecular identification, the ITS1-5.8S-ITS2 region and fragments of the ß-tubulin and elongation factor 1-alpha (EF1-α) genes were sequenced and BLASTn searches done in GenBank. Accession numbers of gene sequences submitted to GenBank were KF811055 for ITS region; KJ639047 for ß-tubulin; and KJ639048 for EF1-α. For all genes used, sequences were 99 to 100% identical to reference isolate CBS164.96 of L. theobromae reported in GenBank (NR_111174, EU673110, and AY640258). Hence, both morphological and molecular characteristics confirmed the fungus as L. theobromae. To confirm fungal pathogenicity, ten 1-year-old healthy plants of C. oleifera were inoculated with the fungus. Mycelial plugs (5 mm) taken from a 7-day-old colony growing on PDA were deposited on wounds with a sterilized knife on leaves and covered with moist cotton. Ten additional control plants were treated similarly but with sterile PDA plugs. Plants were maintained in a moist chamber at 26 ± 2°C for 3 days and then in a greenhouse at 25°C and 40% relative humidity. All the inoculated plants produced typical leaf spot symptoms 3 weeks after inoculation. The fungus was consistently re-isolated from all inoculated plants. Control plants did not show any symptoms. L. theobromae has been reported to cause cankers and dieback in a wide range of hosts and is common in tropical and subtropical regions of the world (1,2), but not previously reported causing disease on C. oleifera. To our knowledge, this is the first report worldwide of leaf spot of C. oleifera caused by L. theobromae. References: (1) S. Mohali et al. For. Pathol. 35:385, 2005. (2) E. Punithalingam. Page 519 in: CMI Descriptions of Pathogenic Fungi and Bacteria. Commonwealth Mycological Institute, Kew, Surrey, UK, 1976.

First Report of Burkholderia andropogonis Causing Bacterial Leaf Spot of Betel Palm in Hainan Province, China.

In May 2009, a severe bacterial disease of arecanut (Areca catechu L.) with an incidence of 100% was observed in a plantation of about 8,400 plants in Wenchang City, Hainan Province, China (19°47.171' N, 110°54.335' E). Symptoms consisted of small circular to elongated brown lesions, ranging from 1 to 105 mm in length and 1 to 21 mm in width, surrounded by yellow halos. White colonies, without fluorescent or diffusible pigments, were consistently recovered on King's B Medium plates from lesions surface-sterilized in 70% ethyl alcohol for 1 min. All isolates were gram-negative and each had a single, polar, sheathed flagellum. Isolates were identified as a Burkholderia sp. based on physiological and biochemical tests: oxidase and catalase positive, negative for arginine dihydrolase, gelatin hydrolysis and starch hydrolysis, and negative for acid production from levan (1,3). Sequences (approx. 1,400 bp each) of the 16S rRNA gene amplified from four isolates using primer pair 27F/1492R (2) (GenBank Accession Nos. JX415481, JX415479, JX415482, and JX415483) shared 99% sequence identity with that of Burkholderia andropogonis strain 6369 (DQ786951). Representative isolates Y11 (China General Microbiological Culture Collection Center No. CGMCC 1.12337), Y30 (CGMCC 1.12338), W15, and W20 were compared with B. andropogonis strain NCPPB No. 1012 and all caused a hypersensitive reaction on leaves of Nicotiana benthamiana. Isolate pathogenicity was tested twice with a total of three replications per isolate. Two young leaves each of 2-year-old arecanut plants were infiltrated with a bacterial suspension of 108 CFU/ml, then covered individually with plastic bags for 48 h, and incubated at 100% relative humidity with 16 h of daylight at 25°C by day and 8 h of darkness at 20°C by night. After 7 days, small water-soaked spots with yellow halos were observed and 60 days after inoculation, lesions developed similar to those caused by B. andropogonis in the field. Koch's postulates were fulfilled by reisolating bacteria from typical lesions on inoculated plants. These bacteria were identical to inoculated strains in colony morphology and sequences of the 16S ribosomal RNA gene. To our knowledge, this is the first report of B. andropogonis infection on betel in Hainan Province, mainland China. This disease was first reported in Taiwan, a province of China. Conditions of high humidity and high temperature support disease outbreaks and infection can result in severe economic losses. In 2012, this disease also appeared on a number of plantations located in other counties. As betel is, economically, the second most important crop in Hainan Province, measures should be required to control this disease, especially in typhoon seasons. References: (1) S. H. Hseu et al. Plant Pathol. Bull. 16:131, 2007. (2) D. J. Lane. In: E. Stackebrandt, et al. Nucleic acid techniques in bacterial systematics. John Wiley & Sons, Chichester, United Kingdom, pp. 115-175, 1991. (3) X. Li and S. H. De Boer. Plant Dis. 89:1132. 2005.

First Report of Stem Bleeding in Coconut Caused by Ceratocystis paradoxa in Hainan, China.

Stem bleeding of coconut was discovered in 2009 in Hainan, China. Affected trunk areas exhibited dark discoloration and a reddish brown or rust-colored liquid bleeding from different points. Stem tissues under the lesions rotted and became brownish yellow to black. Affected plants died within 3 to 4 months after stem symptoms first appeared. Stem bleeding of coconut is known to occur in production areas worldwide. The disease was first reported in Sri Lanka (1), caused severe damage to PB-121 hybrids in Indonesia (2), and is now known to occur in many other coconut-producing countries. However, to our knowledge, this is the first report of the disease in China. A fungus was isolated from lesion margins of diseased coconut trees. Colonies on potato dextrose agar (PDA) were white, became black 1 to 2 days later, and emitted a strong, fruity aroma. The fungus produced conidia, which were cylindrical, colorless to pale brown, and 6.9 to 14.9 × 3.1 to 6.0 µm, and oval, black chlamydospores that were 7.9 to 19.4 × 4.6 to 11.0 µm. The optimum temperature for mycelial growth ranged from 25 to 35°C and it did not grow at temperatures lower than 5°C or higher than 40°C. On the basis of these characteristics, the fungus was identified as Ceratocystis paradoxa (Dade) C. Moreau (anamorph Thielaviopsis paradoxa (de Seynes) Höhn). The internal transcribed spacer (ITS) region was amplified from genomic DNA with primers ITS1 and ITS4 and the PCR products were sequenced (GenBank Accession No. JQ039332). BLAST analysis showed 99% sequence similarity with C. paradoxa (GenBank Accession No. HQ248205.1). Pathogenicity of the fungus was tested by inoculating 10, 3-year-old coconut trees of the cv. green tall at the 12-leaf stage in the field. Agar plugs (5 mm in diameter) from the periphery of 7-day-old C. paradoxa colonies grown on PDA were placed on healthy trunks, rachis, and leaves, which were either wounded or unwounded. Wounds were made with a sterilized cork borer. Sites of the inoculations were wrapped with plastic tape to prevent desiccation; the experiment was repeated three times. Controls received plain PDA discs. Two weeks after inoculation, characteristic rusty brown lesions appeared only on wounded plants that were inoculated with the fungus. A brownish liquid oozed from the points of inoculation. Controls did not show signs of disease development. C. paradoxa was reisolated from the diseased tissues. Infection occurred on wounded sites only, suggesting that wounds may be required for infection. To prevent stem bleeding of coconut trees by C. paradoxa, vigilant cultural practices must be maintained to avoid causing wounds on the trees. References: (1) S. A. Alfieri. Plant Pathol. Circular No. 53. Florida Department of Agriculture Division of Plant Industry, 1967. (2) D. R. N. Warwick and E. E. M. Passos. Trop. Plant Pathol. 34:175, 2009.

P16 and retinoblastoma protein expression in endometrial carcinoma and clinical significance.

OBJECTIVE: To investigate the clinical significance of p16 expression, a product of the cyclin dependent kinase inhibitor CDKN2 (also known as MTS1, multiple tumor suppressor 1) and assess its relationship with retinoblastoma protein expression in the pathogenesis of endometrial cancer. METHOD: p16 and pRb expression were histochemically evaluated, using p16 and RB polyclonal antibodies on paraffin sections of 27 primary endometrial adenocarcinomas with no therapy prior to surgery, through the streptavidin peroxydase conjugated method. Further analyses were carried out using the polymerase chain reaction for exon 1 gene amplification to investigate the mechanism of abnormal p16 expression. RESULT: p16 expression was detected in 100% of normal endometriums and in 74.04% of endometrial carcinomas (p < 0.05). This was significantly associated with tumor cell grade (p < 0.05). PCR analysis of exon 1 in five cases with no detectable p16 expression revealed four homozygous deletions. Additionally, the inverse correlation between RB and p16 expression was confirmed in this study, with 71.42% of tumors demonstrating inverse expression of p16 and RB (p < .005). CONCLUSION: p16 expression decrease is a significant event in endometrial carcinoma pathogenesis, and it is inversely correlated to tumor cell grade. Exon 1 homozygous deletion might be one of the mechanisms of loss of p16 expression. The p16/pRb growth suppressor pathway is targeted in human endometrial carcinoma.

First Report of Root Rot Caused by Phytophthora sansomeana on Soybean in China.

Phytophthora sansomeana E.M. Hansen & Reeser is a newly described species and infects Douglas-fir, alfalfa, and soybean (1). Soybean production is an important part of the local economy in Yili State in Xinjiang Uygur Autonomous Region, northwest China. Unfortunately since 2005, root and stem rot disease has emerged on a number of farms. To identify the causal agent, plant samples with symptoms, including whole plant wilting or yellowing and stunting, were collected from fields during 2005 and 2008. Tissue from the edges of stem lesions was placed on selective lima bean agar (LBA) at 20°C for 3 to 4 days (2,3). Four single zoospore isolates of Phytophthora were obtained and maintained on LBA or 10% V8 juice liquid medium for examination of morphological and physiological characteristics. The colonies on LBA were aerial and rosaceous. The isolates were homothallic, and oogonia and oospores were readily produced in culture after 7 days on LBA plates. Oogonia averaged 38 µm and oospore width ranged from 23 to 48 µm and averaged 31 µm. Antheridia were approximately 15 × 12 µm and predominantly amphigynous in V8 juice. Sporangia were terminal or paragynous on persistent sporangiophores, nonpapillate, ovoid to obpyriform, and measured 52 × 35 µm with an average length/breadth ratio of 1.5. Hyphal swellings were produced in V8 juice 2 days after inoculation. The optimum temperature for growth was approximately 25°C and none occurred at 0 or 35°C. The internal transcribed spacer (ITS) sequence of this Phytophthora species (GenBank FJ966880) agreed 100% with sequences of P. sansomeana isolates deposited in GenBank (GQ853880 and EU925375). Pathogenicity tests were performed by hypocotyl inoculation method (2) using isolate Yili71 and potted soybean cv. Williams. Plants were grown in a growth chamber for 10 days before inoculation in 16-cm-diameter pots (2). Plants were inoculated with 2- × 2-mm plugs of mycelium grown for 4 days on LBA at 25°C, the plugs were adhered to the sides of wounded lower hypocotyls. As controls, plants were inoculated with LBA agar plugs without mycelium (2). Inoculated plants were maintained in a growth chamber at approximately 25°C with a 10-h dark/14-h light cycle and 50% relative humidity and symptom development was monitored daily for 1 week. Wounded stems inoculated with mycelium developed water-soaked lesions, which were similar to those seen on naturally infected plants. A Phytophthora sp. was reisolated from the margins of expanding lesions on wounded stems. To our knowledge, this is the first report of P. sansomeana infection of soybean in China and the threat it may pose to soybean production is unclear. References: (1) E. M. Hansen et al. Mycologia 101:129. 2009. (2) Z. Y. Wang et al. Fungal Genet. Biol. 43:826, 2006. (3) X. B. Zheng. Methods in Phytophthora. Chinese Agriculture Press. Beijing, China, 1995.

Safe zone for transacetabular screw fixation in prosthetic acetabular reconstruction of high developmental dysplasia of the hip.

BACKGROUND: Prosthetic reconstruction of hips with Crowe type-IV developmental dysplasia (a high complete dislocation) is technically demanding. Insufficient osseous coverage and osteopenic bone stock frequently necessitate transacetabular screw fixation to augment primary stability of the metal acetabular shell. We sought to determine whether a previously reported quadrant system for screw fixation of the acetabular cup can be applied in patients with high dislocation of the hip and to define a specialized safe zone for screw fixation in these hips, if needed. METHODS: Using volumetric computed tomographic data and image-processing software, we made three-dimensional reconstructions of the osseous and vascular structures in eighteen hips in twelve patients. We virtually reconstructed a cup in the true acetabulum and dynamically simulated transacetabular screw fixation. We mapped the hemispheric cup into several areas and, for each, measured the distance between the virtual screw and the external iliac (femoral) and obturator blood vessels. In the six patients with unilateral high dislocation of the hip and a relatively normal, contralateral hip, the six relatively normal hips served as controls. RESULTS: Reconstruction of the cup at the level of the true acetabulum shifted the center of rotation anteroinferiorly in the hips with a high, complete dislocation. Screws guided by the quadrant system frequently injured the obturator blood vessels in the hips with a high dislocation. In these patients, the safe zone shifted as a result of moving the prosthetic cup. CONCLUSIONS: The quadrant system, although helpful in determining screw placement in hips with a normal center of rotation, can be misleading and of less value in guiding screw insertion to augment acetabular shells for hips with a high dislocation. We believe that a safe zone specific to hips with a high dislocation should be used to guide transacetabular screw fixation.

[Determination of lamotrigine in the serum and study on pharmacokinetics in rabbits by RP-HPLC].

In the treatment of epileptic patients a method was developed to monitor the lamotrigine concentration by HPLC using a YWG-ODS column and a detector at 305 nm. The linear range was from 0.25 mg/L to 50 mg/L with a mean correlation coefficient of 0.9998. The average recovery was 93.78% and the standard deviation was 2.66%. Within and between-day precisions were 2.4% (n = 9) and 5.3% (n = 5) in RSD respectively. The pharmacokinetics was studied after a single dose of 25 mg/kg for 3 rabbits. Lamotrigine concentrations in serum were assayed and the parameters were computed with 3P87 program. The concentration-time curve of lamotrigine in rabbits fitted to a two compartment model, in which Cmax was 9.34 micrograms/mL, t1/2(Ke) was 8.78 h, and CL/f(s) was 0.69 L/h. The method is rapid, accurate and can be used as routine test in the use of lamotrigine.

[Purification of recombinant hEGF expressed in yeast Pichia pastoris and the study on its characters].

OBJECTIVE: To obtain recombinant human epidermal growth factor(hEGF) that can be used in animal experiments and clinical trial. METHOD: Chemically synthesized hEGF gene was expressed in Yeast Pichia pastoris and the secretory hEGF was purified by Phenysepharose 6 Fast Flow(high sub), Q-sepharose High Performance, and Superdex 30 chromatography, and its characters were studied by respective methods. RESULTS: The purified hEGF doesn't contain pyrogen, endotoxin, or yeast chromosome DNA and the purity reached 98%. The recombinant human EGF has correct molecular weight, pI, N-terminal amino acids sequences, peptide map, ultraviolet spectrum and well-biological activity. CONCLUSION: The purified hEGF is in accord with the requirements for animal experiments and clinical trial which provides the basis of preparing EGF agents for clinical test.

[Analysis and stability study on nimotop injections by RP-HPLC].

A method was developed by using reversed-phase high performance liquid chromatography (HPLC) to analyze nimotop injections. Methyltestosterone was used as an internal standard. The separation was performed on a YWG C18 column with mobile phase of V (methanol):V (water) = 65:35 and detected at 238 nm. The linear concentration range of this method was 5.98 mumol/L-299.0 mumol/L. This method was simple, rapid and has been used to study the stability of nimotop injections. The experimental results showed that the nimotop was stable at higher temperature (50 degrees C) but unstable under light. Nimotop injection should be kept away from light.