Transcription Factors Pmr1 and Pmr2 Cooperatively Regulate Melanin Biosynthesis, Conidia Development and Secondary Metabolism in Pestalotiopsis microspora

Melanins are the common fungal pigment, which contribute to stress resistance and pathogenesis. However, few studies have explored the regulation mechanism of its synthesis in filamentous fungi. In this study, we identified two transcription factors, Pmr1 and Pmr2, in the filamentous fungus Pestalotiopsis microspora. Computational and phylogenetic analyses revealed that Pmr1 and Pmr2 were located in the gene cluster for melanin biosynthesis. The targeted deletion mutant strain Δpmr1 displayed defects in biosynthesis of conidia pigment and morphological integrity. The deletion of pmr2 resulted in reduced conidia pigment, but the mycelial morphology had little change. Moreover, Δpmr2 produced decreased conidia. RT-qPCR data revealed that expression levels of genes in the melanin biosynthesis gene cluster were downregulated from the loss of Pmr1 and Pmr2. Interestingly, the yield of secondary metabolites in the mutant strains Δpmr1 and Δpmr2 increased, comparing with the wild type, and additionally, Pmr1 played a larger regulatory role in secondary metabolism. Taken together, our results revealed the crucial roles of the transcription factors Pmr1 and Pmr2 in melanin synthesis, asexual development and secondary metabolism in the filamentous fungus P. microspora.

First Report of Pestalotiopsis microspora Causing Leaf Blight of Banana in Bangladesh

Banana (Musa sp.) is one of the most important fruit crops in the world. It is also a very popular fruit crop and cultivated widely in Bangladesh. Banana diseases are one of the limiting factors for its production. Recently, a new banana leaf blight was detected in various districts of Gazipur, Bangladesh, with an incidence of 5 to 10% in June 2020 and 15 to 20% in January 2021. The initial symptoms of the disease were narrow dark brown lesions (2 to 5 x 5 to 12 mm) that later became irregular brown spots (10 to 15 x 5 to 7 mm). The lesions gradually spread from the middle of the leaf to the margin and dark brown spots appeared on the diseased leaves. There was a clear golden yellowish boundary around the spot. Blighted tissue often covered one-thirds to one-half of the infected leaves. To isolate the pathogen, 100 diseased leaves were collected from five different locations in Gazipur, Bangladesh. Small pieces (5x5 mm) were cut from the margins of lesions and surface sterilized with 75% ethanol for 30 s followed by 1% NaClO for 1 min. The samples were then rinsed three times with sterile distilled water, dried on sterilized filter paper, and placed on 1% water agar at 25°C for 7 days. Hyphal tips were then excised, placed on PDA and incubated at 25°C for 7 days. From the 20 isolates obtained, the colony characteristics and conidial morphology of three isolates, BLS_BU1, BLS_BU2, and BLS_BU3, were examined. The colony of all of three isolates was white, cottony, and circular in growth. The acervuli were black and covered all the culture plate. Conidia of all the isolates were 5-celled, fusiform, and wider in the middle than the apical and basal cells. The three internal cells were olivaceous, concolourous, and slightly constricted at the septae; the terminal cells were hyaline (Shi et al. 2015). The conidium measured 20.3 ± 1.2 to 22.7 ± 1.8 by 7.2 ± 0.6 to 8.6 ± 0.4 μm. The mean lengths of the two to four hyaline apical appendages were 20.5 to 30.25 μm and the hyaline basal appendage was 6.1 to 7.6 μm (Han et al. 2019). DNA was extracted from the fungal colony using a DNeasy Plant Mini Kit (Qiagen). PCR was performed with primers ITS1/ITS4 ITS region and Sanger sequenced by Macrogen (Seoul, Korea) (White et al. 1990). Isolates BLS_BU1 (MH707065), BLS_BU2 (MH707065), and BLS_BU3 (MH712283) had a sequence similarity of over 99% with GenBank reference Pestalotiopsis microspora (MH707065) of National Center for Biotechnology Information (NCBI) database. The reconstructed phylogenetic tree also confirmed their phylogenetic position. To assess pathogenicity, the leaves of four 2-month-old healthy plants were needle wounded and inoculated with a spore suspension (106 spores/ ml) harvested from 10-day-old cultures of isolate BLS_BU1. As a control treatment, five leaves of two healthy plants were inoculated with sterile distilled water. Treated plants were maintained in the field with average temperature ranging from 28°C to 30°C and relative humidity from 75% to 80%. After 2 weeks, all inoculated leaves produced characteristic symptoms similar to those observed in the field. However, the control plants did not develop any symptoms. Pestalotiopsis microspora from the inoculated leaves was successfully reisolated, thus confirmed that P. microspora was the cause of leaf blight of banana. To our knowledge, banana appears to be a new host of P. microspora. this This is the first report of leaf blight of banana caused by P. microspora in Bangladesh.

DIAGNOSIS PENYAKIT GUGUR DAUN KARET (Hevea brasiliensis Muell. Arg.)

One of the causal of the low rubber production is the presence of plant diseases. Important diseases in rubber plants generally cause symptoms of leaf fall, due to Colletotrichum spp., Corynespora sp., and Oidium sp. Currently, there is an incidence of new rubber leaf fall disease with symptoms that are different from the diseases previously found in rubber plantations. This disease is widespread in Sumatra, Kalimantan, and Southeast Asia. There are many suspicions about the pathogens that cause the disease, but there is no precise diagnosis. Therefore, an accurate diagnosis is needed as a basis for determining an effective and efficient disease control strategy. This research was carried out to determine the causal agents of leaf fall disease with symptoms of round leaf spots that can cause leaf fall. Diagnosis was carried out by isolating the pathogen from several rubber clones, inoculating the pathogen to healthy rubber plants, identifying morphologically and molecularly, and re-isolating from inoculated plants. The results of Koch's postulates and morphological and molecular identification determined that the causal agents of leaf fall disease at rubber plants with round spots was the fungus Pestalotiopsis microspora.

Prevalence of Non-Dermatophytic Molds Associated with Cutaneous Mycoses in Cattle in Abia and Imo States, Nigeria

Aims: To study the prevalence and identification of non-dermatophytic molds associated with cattle in Abia and Imo States, Nigeria. Study Design: The systematic random sampling method was adopted. Place and Duration of Study: A total of 2255 cattle was encountered, out of which 451 skin samples from both infected and asymptomatic animals were sampled from six cattle markets in Abia and Imo States, Nigeria between January and August, 2018. Methodology: The 451 samples were analysed for their colonial and microscopic morphology and molecular analysis. Polymerase chain reaction of the 16SrRNA internal transcriber spacer (ITS) sequence techniques were carried out on the isolates. Pathogenicity of the isolates were determined. Results: A total of 16 non-dermatophytic molds were obtained from 451samples analysed at different frequency of occurrences from the cattle skins in both states and these include Aspergillusfumigatus (3.6%), Aspergillus terreus (2.7%), Aspergillus wewitschiae (13.5%), Aspergillus flavus (10.0%), Aspergillus aculeatus (9.0%), Aspergillus sydowii (5.0%), Fusarium solani (3.2%), Fusarium lichenicola (17.9%), Fusarium succisae (12.0%), Fusarium oxysporum (2.0%), Penicillium citrinum (3.0%), Curvularia kusanol (0.6%), Cladosporium tenuissimum (4.9%), Pestalotiopsis microspora (0.1%), Talaromyces kendrickii (0.1%) and Absidia specie (12.9%). Conclusion: The study revealed that non-dermatophytic molds were highly prevalent and are possible causative agent of cutaneous mycoses in cattle. Pathogenicity evaluation carried out in this study revealed that Aspergillus welwitschiae, Cladosporium tenuissimum and Absidia sp. were highly virulent.

Foliar endophytic fungi of Theobroma cacao stimulate more than inhibit Moniliophthora spp. growth and behave more as an endophytes than pathogens.

The two most disastrous diseases of Theobroma cacao in Ecuador are caused by the pathogenic fungi Moniliophthora roreri (MR, Frosty pod) and M. perniciosa (MP, Witches' broom). Both diseases are prevalent in Ecuador since its detection in 1916 and 1921, respectively. One hundred and twenty-six isolates were isolated from healthy T. cacao leaves, originated from five nurseries in the Ecuadorian Coast. Isolates were screened in vitro for their stimulation/inhibition of growth of MR & MP. The endophytic fungi influenced the growth of Moniliophthora spp. in different manners, 91/126 of the tested isolates stimulated somehow the colony growth of both pathogens, and only 30 and 5 isolates always inhibited the mycelial growth of MR & MP, respectively. The highest percentage of growth inhibitions against MR was 71%, but quite lower for MP (18%). Only two isolates caused symptoms of chlorosis and necrosis in leaves and fruits Phomopsis spp. (Ascomycota) and Psathyrella sp. (Basidiomycota). Twenty-four isolates from 11 taxa caused necrosis only fruits (Ascomycota: Phomopsis spp., Phoma sp., Colletotrichum gloeosporioides s.l., Fusarium decemcellulare, F. equiseti, F. solani, Nectria pseudotrichia, Pestalotiopsis microspora, Didymosphaeria futilis, Xylaria venosula and Basidiomycota: Ceriporia lacerata) and four isolates/taxa infected only leaves (Phomopsis spp., Pestalotiopsis microspora, Nigrospora sphaerica and one unidentifiable isolate of Xylariaceae sp.). The non-pathogenic isolate, Hypoxylon investiens, inhibited MR in 71%, but also stimulate the growth of MP in 3%. The second-best isolate (Lasiodiplodia theobromae) only inhibit MR and MP in 58 y 15%, respectively; and, although the isolate was not pathogenic, the specie is risky to develop a biological control agent. There was no promising isolate against both MR & MP.

Exploring the Antibacterial Activity of Pestalotiopsis spp. under Different Culture Conditions and Their Chemical Diversity Using LC–ESI–Q–TOF–MS

As a result of the capability of fungi to respond to culture conditions, we aimed to explore and compare the antibacterial activity and chemical diversity of two endophytic fungi isolated from Hyptis dilatata and cultured under different conditions by the addition of chemical elicitors, changes in the pH, and different incubation temperatures. Seventeen extracts were obtained from both Pestalotiopsis mangiferae (man-1 to man-17) and Pestalotiopsis microspora (mic-1 to mic-17) and were tested against a panel of pathogenic bacteria. Seven extracts from P. mangiferae and four extracts from P. microspora showed antibacterial activity; while some of these extracts displayed a high-level of selectivity and a broad-spectrum of activity, Pseudomonas aeruginosa was the most inhibited microorganism and was selected to determine the minimal inhibitory concentration (MIC). The MIC was determined for extracts man-6 (0.11 μg/mL) and mic-9 (0.56 μg/mL). Three active extracts obtained from P. mangiferae were analyzed by Liquid Chromatography-Electrospray Ionization-Quadrupole-Time of Flight-Mass Spectrometry (LC–ESI–Q–TOF–MS) to explore the chemical diversity and the variations in the composition. This allows us to propose structures for some of the determined molecular formulas, including the previously reported mangiferaelactone (1), an antibacterial compound.