Population ecology of Thrips palmi (Thysanoptera:Thripidae) in orchid farms in Thailand

The population dynamics and in-farm distribution of Thrips palmi Karny were evaluated in two orchid farms, one in the Bangkok metropolitan area and the other in Ratchaburi Province, Thailand. Yellow sticky traps were hung above the orchid canopy (three traps/220 m²), and the trapped adults were counted weekly from November 2009 to October 2010 at the first location and from January to December of 2012 at the second location. T. palmi nymphs and adults were both counted weekly on 300 orchid panicles in an area of 2,200 m² at both locations. We found that the T. palmi population dynamics at the first location was represented by a W-shaped curve, with the distribution clumped throughout the year, whereas the curve was J-shaped at the second location, with the distribution mostly clumped. Qualitative surveys of thrips species were conducted on ten different orchid genera in ten locations and on 20 different Dendrobium hybrids in 20 locations. Five random sampling plots (1 × 4 m²) were examined on each farm. The results indicated that only T. palmi was found on every farm. Moreover, quantitative comparison among five orchid types revealed that Dendrobium flowers with darker color are more attractive to T. palmi. However, this phenomenon does not coincide with Oncidium sp. and Mokara sp. because of their unfavorable morphology for thrips behavior.     

Insect-Specific Polyketide Synthases (PKSs), Potential PKS-Nonribosomal Peptide Synthetase Hybrids,and Novel PKS Clades in Tropical Fungi

Polyketides draw much attention because of their potential use in pharmaceutical and biotechnological applications. This study identifies an abundant pool of polyketide synthase (PKS) genes from local isolates of tropical fungi found in Thailand in three different ecological niches: insect pathogens, marine inhabitants, and lichen mutualists. We detected 149 PKS genes from 48 fungi using PCR with PKS-specific degenerate primers. We identified and classified 283 additional PKS genes from 13 fungal genomes. Phylogenetic analysis of all these PKS sequences the comprising ketosynthase (KS) conserved region and the KS-acyltransferase interdomain region yielded results very similar to those for phylogenies of the KS domain and suggested a number of remarkable points. (i) Twelve PKS genes amplified from 12 different insect-pathogenic fungi form a tight cluster, although along with two PKS genes extracted from genomes of Aspergillus niger and Aspergillus terreus, in reducing clade III. Some of these insect-specific fungal PKSs are nearly identical. (ii) We identified 38 new PKS-nonribosomal peptide synthetase hybrid genes in reducing clade II. (iii) Four distinct clades were discovered with more than 75% bootstrap support. We propose to designate the novel clade D1 with 100% bootstrap support “reducing clade V.” The newly cloned PKS genes from these tropical fungi should provide useful and diverse genetic resources for future research on the characterization of polyketide compounds synthesized by these enzymes.One hallmark of tropical countries is the tremendous availability and diversity of natural resources. Tropical forests, freshwater reservoirs, and seas are home to an uncountable number of species, ranging from microorganisms (e.g., bacteria, fungi, and protozoa) to invertebrates to vertebrates to plants. Thailand is no exception. The country has a large collection of fungi found in different niches and habitats in its ecosystems. Interesting groups include fungi that are associated with insects, those that inhabit the sea, and those that are in lichen complexes; these are referred to here as insect fungi, marine fungi, and lichenized fungi, respectively. The first group is of particular interest because it represents a remarkable relationship (in this case, pathogenesis) between the fungi and their insect hosts. These entomopathogenic fungi were isolated from the dead insect bodies in different stages (e.g., larvae, pupae, nymphs, or adults). The marine fungi used in this study were mostly isolated from the living or dead plant parts floating at the seashore, whereas the lichen mutualistic fungi were isolated from lichen complexes on the bark of trees in tropical forests in Thailand. All these fungal isolates were deposited in National Center for Genetic Engineering and Biotechnology (BIOTEC) Culture Collection (BCC). The BCC has one of the richest collections (approximately 400 species and 5,000 isolates) of insect fungi in the world (19).Secondary metabolites may play an important role in organisms that synthesize them, for example, in spore development (7), protection, or host virulence (5). Polyketides (PKs) are natural secondary metabolite compounds derived from the condensation of acyl coenzyme A subunits in a head-to-tail manner, and they have a tremendous diversity in structure (33). Structural diversification of the PKs includes a variation in the number of subunits, types of subunits, degree of chemical reduction of the β-keto thioester, extent of stereochemistry of the α-keto group at each condensation, and subsequent processing (e.g., cyclicization) (25, 28, 33). The high therapeutic and economic value of PK compounds has attracted the interest of drug companies and government research agencies. Some PKs are commercially available for medical treatments, such as grahamimycin and patulin (antibiotics), lovastatin and compactin (cholesterol-lowering agents), griseofulvin (an antibiotic/antifungal agent), and monocerin (an antifungal agent).Enzymes that synthesize the PKs are called PK synthases (PKSs). PKSs are multifunctional enzymes that are composed of three principal domains: ketoacyl synthase (KS), acyltransferase (AT), and acyl carrier protein (ACP). Fungal PKSs are type I, multifunctional large enzymes and use an iterative strategy to synthesize PKs. They can be divided into two groups, nonreducing (NR) and reducing (4), and further subdivided into NR subclades I, II, and III and reducing subclades I, II, III, and IV (26). NR PKSs include those synthesizing pigments or aflatoxin. Reducing PKSs are involved in the synthesis of PK compounds with various chemical reductions in structure. Apart from the three major domains (KS, AT, and ACP) present in all PKSs, reducing PKSs contain three additional domains, i.e., dehydratase, enoyl reductase, and ketoreductase, which are involved in the reduction of the keto group to various stages (i.e., alcohol, unsaturated thiolester, and full saturation, respectively), therefore enhancing diversity of the PK structure.Kroken et al. (26) studied putative amino acid sequences of the PKS genes previously characterized in fungi and the PKS genes discovered from the genome sequencing projects for eight fungal species in the Ascomycota. PKS genes were found only in the genomes of the Pezizomycotina and not in the sequenced genomes of either Ascomycota in the Taphrinomycota or Saccharomycotina or Basidiomycota in the Hymenomycetes. Thus, we focused our search on the fungi in this subphylum. We aimed to mine valuable PKS genes from this fungal resource. One of the main objectives is to find novel secondary metabolites useful for medical or agricultural applications. One highly regarded example is the “vegetable caterpillar,” where the fungus Cordyceps sinensis grows on Hepialidae caterpillars. The fungus has long been used in traditional Chinese medicine. Extracts of Cordyceps sinensis were reported to have a variety of therapeutic effects, for example, antitumor (6), antioxidant (42), and antiaging (24) activities. The C. sinensis-Hepialidae pair is also called the “body snatcher”. This name comes from the fact that the fungus infects and consumes the insect tissue and fills up the insect cavity with its mycelia. Thus, another objective is to find metabolites involved in interaction between fungal pathogens and their insect hosts. Insect pests pose tremendous losses to humans in regard to health issues (vectors of diseases) and economic issues (crop plant losses by insect pathogens and building structure damage by termites). Little was known regarding the roles of PKs in producing fungi on their interaction with insect host. Better understanding of this relationship might have implications for insect control.We conducted our PKS screening using PCR with the degenerate KA series primers (2). In addition to our preliminary PKS screening with these primers in a few fungi (2), the KA series primers were used to clone the reducing PKS gene for radicicol biosynthesis from the fungus Pochonia chlamydosporia, and later its whole biosynthetic cluster was revealed (37). Here, the method and the primers were also proven to be successful in finding rich resources of hidden metabolic pathways for PK biosynthesis from 48 fungi that were isolated in Thailand and, particularly, have no genome sequences determined. In addition, more than 200 PKS genes were identified from our genome analysis of 13 filamentous fungi.     

Comparative analysis of <Emphasis Type="Italic">Mycobacterium avium</Emphasis> subsp. <Emphasis Type="Italic">paratuberculosis</Emphasis> isolates from cattle,sheep and goats by short sequence repeat and pulsed-field gel electrophoresis typing

Background  

Mycobacterium avium subsp. paratuberculosis (Map) causes the chronic enteritis called paratuberculosis mainly in cattle, sheep and goats. Evidences that point out an association between Map and Crohn's Disease in humans are increasing. Strain differentiation among Map isolates has proved to be difficult and has limited the study of the molecular epidemiology of paratuberculosis. In order to asses the usefulness of the PCR based short sequence repeat (SSR) analysis of locus 1 and locus 8 in the epidemiological tracing of paratuberculosis strains we here compare for the first time the results of SSR and SnaBI-SpeI pulsed-field gel electrophoresis (PFGE) typing methods in a set of 268 Map isolates from different hosts (cattle, sheep, goats, bison, deer and wild boar).     

Culture degeneration in conidia of Beauveria bassiana and virulence determinants by proteomics

The quality of Beauveria bassiana conidia directly affects the virulence against insects. In this study, continuous subculturing of B. bassiana on both rice grains and potato dextrose agar (PDA) resulted in 55 and 49 % conidial yield reduction after 12 passages and 68 and 60 % virulence reduction after 20 and 12 passages at four d post-inoculation, respectively. The passage through Tenebrio molitor and Spodoptera exigua restored the virulence of rice and PDA subcultures, respectively. To explore the molecular mechanisms underlying the conidial quality and the decline of virulence after multiple subculturing, we investigated the conidial proteomic changes. Successive subculturing markedly increased the protein levels in oxidative stress response, autophagy, amino acid homeostasis, and apoptosis, but decreased the protein levels in DNA repair, ribosome biogenesis, energy metabolism, and virulence. The nitro blue tetrazolium assay verified that the late subculture's colony and conidia had a higher oxidative stress level than the early subculture. A 2A-type protein phosphatase and a Pleckstrin homology domain protein Slm1, effector proteins of the target of rapamycin (TOR) complex 1 and 2, respectively, were dramatically increased in the late subculture. These results suggest that TOR signalling might be associated with ageing in B. bassiana late subculture, in turn affecting its physiological characteristics and virulence.     

A class Vb chitin synthase in Colletotrichum graminicola is localized in the growing tips of multiple cell types, in nascent septa, and during septum conversion to an end wall after hyphal breakage

Summary. Previous complementation of a chitin synthase class Vb null mutant (Colletotrichum graminicola chsA) indicated that the encoded protein is responsible for approximately 30% of the conidial chitin, is essential for conidial wall strength in media with high water potential, and contributes to strength of hyphal tips. We complemented a chsA null mutant with chsA fused to the green-fluorescent protein (sgfp) gene driven by a heterologous constitutively expressed promoter. Comparisons of the strain with the ectopic chsA-sgfp to the wild type indicated that ChsA-sGFP serves the same biological functions as ChsA in that like the wild type, the chsAΔ chsA::sgfp (EC) had conidia that did not explode and hyphal tips that did not swell. Confocal microscopy of ChsA-sGFP (EC) cells stained with the membrane stain FM 4-64 (N-(3-triethylammoniumpropyl)-4-(6-(4-(diethylamino)phenyl)hexatrienyl)pyridinium dibromide) indicated that ChsA is localized in the plasma membrane of the following: growing apices of hyphal branches, conidiophores, and falcate and oval conidia; in nascent septa; and in septa that are being converted to an end wall after hyphal breakage. The data support the hypothesis that chsA either directly or indirectly encodes the information for its localization, that ChsA is localized in the plasma membrane, and that the class Vb enzyme produces chitin synthase in multiple cells and after wall breakage. Correspondence and reprints: Department of Plant Pathology, University of California, Davis, CA 95616-8680, USA.