Shot Hole Research Articles

Morphological Characterization and Biological Management of Gloeosporium ampelophagum (Pass.) Sacc Causing Anthracnose of Grapes in India

Grape an important fruit crop, has been found to face a serious threat due to anthracnose disease. The disease on leaves appeared as small irregular dark brown lesions, which later developed greyish centre with dark brown margins that eventually dried and dropped resulting in peculiar shot hole appearance. On twigs (vines) the disease initially appeared as light brown circular lesion which on elongation became elliptical and developed sunken ashy grey centre. Coalescing of numerous such lesions culminated in canker formation. Berry symptoms were initiated as circular reddish brown lesions, which later coalesced, resulting in shrivelling and mummification of berries. The pathogen was isolated on potato dextrose agar medium and its pathogenicity was proved. The fungus produced circular, cottony colony with light green centre and creamish margins which later turned olive green with radial furrows. Acervuli and conidia were formed 10 days after incubation at 25±2 oC. Conidia (6.21 × 3.87μm) were oblong and hyaline to brownish in colour. Based on its colony characters, morphological characters and by comparing with authentic descriptions as well as through pathogenicity the pathogen causing anthracnose disease of grapes was identified as Gloeosporium ampelophagum (Pass.)Sacc. The fungus showed highest mycelial sporulation of 0.81×106/ml on oat meal agar with a pH 6.5 at 25-30 oC. Among the bio-agents screened, Trichoderma harzianum exhibited maximum inhibition in mycelial growth of 62.53 per cent that can be effectively used for the management of the disease.

First Report ofColletotrichum gloeosporioidesCausing Anthracnose on Frafra Potato (Coleus rotundifolius) in Ghana

First Report of<i>Colletotrichum gloeosporioides</i>Causing Anthracnose on Frafra Potato (<i>Coleus rotundifolius</i>) in Ghana

Characterization of some fungal pathogens causing anthracnose disease on yam in Cross River State, Nigeria.

Yam anthracnose is one of the most serious fungal diseases affecting white and water yam production. Screening of available landraces for new sources of durable resistance to the pathogen is a continuous process. In the present study, the pathogens causing anthracnose in Dioscorea alata and Dioscorea rotundata farms in Cross River State yam belt region were characterized. Diseased yam leaves with anthracnose symptoms collected from the farms were used in the isolation, purification and, identification of C. alatae strains using morphological, cultural, and molecular methods. Leaf chlorosis, leaf edge necrosis, blights, dark brown to black leaf spots, shot holes, necrotic vein banding and vein browning were the predominantly observed symptoms. Seven isolates of C. alatae, Ca5, Ca14, Ca16, Ca22, Ca24, Ca32 and Ca34, and one isolate of Lasidioplodia theobromae, Lt1 were found to be associated with yam infection in Cross River State, with Lt1 as the most prevalent, occurring in all the locations. These isolates were classified into four forms which included the slow-growing grey (SGG), the fast-growing grey (FGG), the fast-growing salmon (FGS), and the fast-growing olive (FGO). Sequence analysis of the ITS region revealed <80% nucleotide identity between the isolates and the reference C. gloeosporioides. Pathogenicity test showed that all the isolates displayed typical symptoms of anthracnose disease as were observed in the field, but Lt1 was the most virulent. Inoculation of 20 D. alata and 13 D. rotundata landraces with isolate Lt1, showed that 63.64% of the landraces were susceptible while 36.36%were resistant. D. alata landraces were the most susceptible. This study revealed that anthracnose is prevalent and may assume an epidemic dimension in the yam growing communities of the state. There is need for increased effort in the breeding of yam for anthracnose resistance.

Rapid and cost‐effective detection of Fusarium euwallaceae from woody tissues

AbstractThe polyphagous shot hole borer (PSHB) Euwallacea fornicatus is an ambrosia beetle that poses a serious threat to hundreds of tree species in invaded countries. In its invaded range, it relies on a mutualistic fungus, Fusarium euwallaceae, for colony establishment and nutrition. Together, the beetle–fungus complex can cause Fusarium dieback disease that can lead to the death of highly susceptible hosts. The key to mitigation of the spread and control of PSHB is its rapid detection. Current identification relies on DNA extraction and sequencing of barcoding genes of the beetle and/or the fungus, which is expensive and time‐consuming. Often the beetle is not present in a sample, and isolation and purification of the fungus is needed before employing molecular procedures. Because PSHB has a strong association with its fungal symbiont, at least in its invaded range, and the fungus can infect trees without successful PSHB colony establishment, a molecular tool that can rapidly detect F. euwallaceae from infected wood would aid monitoring efforts. Here we developed a PCR amplification protocol that targets a species‐specific gene present in F. euwallaceae from within infected wood of various hosts without prior fungal isolation, DNA purification or sequencing. The technique can detect F. euwallaceae within minimal woody material (c.15 mg) and even from degraded samples of many hosts. Additionally, identification of F. euwallaceae using lysate prepared from mycelia provided a reliable secondary measure. This method drastically reduces the time and costs associated with the identification of F. euwallaceae from field samples.

Characteristics of peach twigs expressing spring canker bacterial shot holes and the effects of the early elimination of spring cankers

モモせん孔細菌病の春型枝病斑の早期の発見と切除を目的として，その発生前の生育状況と病斑発生について把握するため，2016年，2017年及び2021年の計3年間，愛知県長久手市内のモモ“日川白鳳”栽培ほ場にて調査した。春型枝病斑が発生した枝は発生しなかった枝と比較して，葉芽の発芽率が低く，枝ごとの平均葉長が短く推移する傾向が見られた。

​Phoma Blight of Soybean in Kashmir: Etiology, Relative Yield Losses and Critical Stage of Management Intervention

Background: Soybean leaf blight has been viewed as a possible biotic stress responsible for decreasing yield potential of soybean in Kashmir over the years. Therefore, its etiology and recording associated yield loss were deemed necessary corresponding to baseline findings for deciding any chemical or non-chemical intervention in disease management. Methods: Field and laboratory investigations were undertaken during crop periods of 2019 and 2020. Disease specimens were collected from various locations across valley and the pathogen was isolated on Potato Dextrose Agar medium. To identify the host range of soybean isolate, nine pulse crops were tested under controlled conditions (Tem. 22±3°C and RH greater than 80%). The relative yield loss and critical stage of chemical intervention were assessed by exposing soybean populations to disease at different phenological stages which created five different levels of disease in a field experiment laid in RBD with four replications. Result: Phoma sojicola (syn. Ascochyta sojicola) was associated pathogen of this disease of soybean in Kashmir. Typical disease symptoms on leaves comprised of roughly circular and brown lesions (up to 20 mm diameter) with concentric rings having interspersed pycnidia. Most often the diseased tissue fall apart and gives it a shot hole expression. Radial daily mycelial growth of the pathogen was 3.62 mm colony was grey olivaceous in the centre and light olivaceous towards periphery. Conidia were hyaline, oblong to ellipsoidal and 1-2 celled with average dimensions of 7.98 x 2.87 µ. Chlamydospores were brown olivaceous, globose to sub-globose with average dimensions of 16.89 x 9.30 µ. After artificial inoculation, Phaseolus vulgaris, Vigna sinensis, V. radiata, V. mungo, Cicer arietinum, Vicia faba and Cajanus cajan manifested disease symptoms after variable incubation periods of 8-13 days, while as Lens esculenta and Pisum sativum resisted the invasion. Early appearance of the Phoma blight (V-1 stage) in soybean can reach a terminal intensity of 67.16 per cent besides causing 51.72 per cent yield loss. Tolerable yield loss (5.63%) was achieved only when the crop was maintained disease free up to R-3 (beginning pod development) stage.

Temporal Dynamics of Incidence of Shot Hole Disease Affected by Training Systems and Cultivar Susceptibilities in an Integrated Plum Orchard.

Shot hole disease (SHD) can cause severe epidemics in plum orchards, depending on cultivar susceptibility and training system; however, the combined effect on the progress of temporal disease and on the possible reduction in SHD in the disease management was not investigated. The aim of this 3-year study was (i) to monitor and analyze the temporal dynamics of SHD progress under four training systems (4 × 1.5, 4 × 2, 5 × 2.5 and 6 × 3 m) and on four plum cultivars (‘Čačanska lepotica’, ‘Bluefre’, ‘Stanley’ and ‘President’) in an integrated plum orchard; (ii) to identify those time periods when training system and cultivar combinations can reduce the disease development. Both SHD incidences and the area under the disease progress curves (AUDPC) were significantly affected by the training system, cultivar and year. Plum cultivars with high or mid–high susceptibility to SHD showed continuous SHD development from May to November, while cultivars with low susceptibility to SHD showed no symptoms until mid-summer and then progressed slowly until November. High (4 × 1.5 m) vs. low (6 × 3 m) density training systems reduced SHD incidence and AUDPC consistently for three cultivars (‘Čačanska lepotica’, ‘Stanley’ and ‘President’) in September, October and November, compared to the high-density training system. Only cv. ‘Bluefre’ showed no effect either on disease incidence or AUDPC, due to very high disease incidences in all training systems from September to November. In conclusions, combinations of training system and cultivar can significantly reduce SHD incidence, which may be successfully used as a part of the integrated pest management approach during the establishment new plantations.

An Assessment of the Potential Economic Impacts of the Invasive Polyphagous Shot Hole Borer (Coleoptera: Curculionidae) in South Africa.

Studies addressing the economic impacts of invasive alien species are biased towards ex-post assessments of the costs and benefits of control options, but ex-ante assessments are also required to deal with potentially damaging invaders. The polyphagous shot hole borer Euwallacea fornicatus (Coleoptera: Curculionidae) is a recent and potentially damaging introduction to South Africa. We assessed the potential impact of this beetle by working across economic and biological disciplines and developing a simulation model that included dynamic mutualistic relations between the beetle and its symbiotic fungus. We modeled the potential growth in beetle populations and their effect on the net present cost of damage to natural forests, urban trees, commercial forestry, and the avocado industry over 10 yr. We modeled high, baseline, and low scenarios using discount rates of 8, 6, and 4%, and a plausible range of costs and mortality rates. Models predicted steady growth in the beetle and fungus populations, leading to average declines in tree populations of between 3.5 and 15.5% over 10 yr. The predicted net present cost was 18.45 billion international dollars (Int. $), or about 0.66% of the country's GDP for our baseline scenario ($2.7 billion to $164 billion for low and high scenarios). Most of the costs are for the removal of urban trees that die as a result of the beetle and its fungal symbiont, as has been found in other regions. We conclude that an ex-ante economic assessment system dynamics model can be useful for informing national strategies on invasive alien species management.

Mapping the distribution and tree canopy cover of Jacaranda mimosifolia and Platanus \xd7 acerifolia in Johannesburg\u2019s urban forest

This study investigated the distribution and the tree canopy cover (TCC) of the two most prominent street trees (Jacaranda mimosifolia and Platanus × acerifolia) in Johannesburg, using the multispectral SPOT 6 satellite data and field survey GPS points. The importance of the spectral bands (Blue, Green, Red and NIR) and the NDVI index in discriminating between the tree species was quantified using five separability indices (Divergence, Bhattacharyya, Transformed Divergence, Jeffries-Matusita and M-statistic). The visual comparison of the Blue band and the NDVI histograms between the two species and other vegetation type showed the lowest feature overlap, suggesting the highest separability between paired classes. This was further supported by the highest Divergence value for the Blue band (3.68) and NDVI index (2.48) followed by the M-statistic (0.8 and 0.73, respectively) indicating good to moderate separability between the two species, respectively. The results were also consistent with the RF classification where the Blue band and NDVI index were the most important variables for the discrimination between the two species with an overall accuracy of 88% (kappa = 8). The TCC of J. mimosifolia and P. × acerifolia constituted 38% of the total vegetation cover in the city. These findings not only would help prioritize the increase of targeted vegetation cover in low cover areas, but will also provide a valuable information for assessment and protection of vulnerable species such as P. × acerifolia from the threat of the polyphagous shot hole borer, Euwallacea fornicatus in Johannesburg.

Isolation and Identification of Pennogenin Tetraglycoside from Cestrum nocturnum (Solanaceae) and Its Antifungal Activity against Fusarium kuroshium, Causal Agent of Fusarium Dieback.

Antifungal assay-guided fractionation of the methanolic crude extract of Cestrum nocturnum (Solanaceae), popular known as ‘lady of the night’, led the isolation and identification of the steroidal saponin named pennogenin tetraglycoside, which was identified for the first time in this plant species by spectroscopic means. The crude extract, fractions and pennogenin tetraglycoside exhibited mycelial growth inhibition of Fusarium solani and F. kuroshium. F. solani is a cosmopolitan fungal phytopathogen that affects several economically important crops. However, we highlight the antifungal activity displayed by pennogenin tetraglycoside against F. kuroshium, since it is the first plant natural product identified as active for this phytopathogen. This fungus along with its insect symbiont known as Kuroshio shot hole borer (Euwallacea kuroshio) are the causal agents of the plant disease Fusarium dieback that affects more than 300 plant species including avocado (Persea americana) among others of ecological relevance. Scanning electron microscopy showed morphological alterations of the fungal hyphae after exposure with the active fractions and 12 phenolic compounds were also identified by mass spectrometry dereplication as part of potential active molecules present in C. nocturnum leaves.

Application of integrated drilling and stamping technology in gas extraction through layer drilling

In coal mine gas extraction in China, the current hydraulic permeability enhancement measures generally have complex processes, low adaptability, long operation time, and high labor intensity. This makes it challenging to meet the requirements of coal mining enterprises for safe and efficient mining, and there is an urgent need to develop new technologies to enhance gas extraction and production. This paper proposed an integrated drilling and stamping technology to enhance gas extraction and production and integrates drilling, hydraulic jet fracturing, and hydraulic punching to enhance the permeability of coal seams. A field test was conducted using the specially-developed integrated drilling and stamping equipment to extract gas from the 16101 bottom pumping lane penetration hole in the Jiulishan Mine, Jiaozuo, Henan. The test results show that compared with the hydraulic punching technology previously used in the mine, the punching time of the soft coal seam was shortened by 66–75%, the coal output was increased by 1.7 times, and the punching hole aperture was increased by 1.3 times. Hydraulic injection fracturing was successfully performed to increase the permeability of the hard coal seams, and the fracturing formed a shot hole depth of 345–539 mm. After the integrated drilling and stamping of the drill holes, the coal output, gas extraction concentration, pure gas extraction volume, and coal seam permeability coefficient increased by 2.4, 2.2, 4, and 37.3 times, respectively. The gas flow decay coefficient of the drills holes was also further reduced, which significantly improved the extractionefficiency. Thus the integrated drilling and stamping technology can transform the process of gas extraction from regular extraction to quick, economic, pure, and clean extraction. Thus, this technology has large applicable value for underground gas management in coal mines.

First Report of Leaf Spot Disease on Cinnamomum camphora (Camphor Tree) Caused by Epicoccum poaceicola in China.

As an important industrial, pharmaceutical and evergreen shade tree (Singh and Jawaid 2012), the camphor tree (Cinnamomum camphora) has been coppiced in Jiangxi Province, China. From 2017 to 2020, we noticed many camphor trees with leaf spots, with an incidence estimated at 50 to 75%, which could severely inhibit leaf growth and reduce their biomass. A dark-green circle with a watery spot appeared on the infected leaves at the initial stage, and necrosis with forming shot-spots surrounded by yellow halos occurred (Figure 1 A). Five leaves with typical symptoms were sampled and washed with tap water for ca. 15 min. Isolation and morphological analysis were performed following the method of Bao et al. (2019). Among 61 fungal isolates, 49 showed the same culture characters. Colonies on PDA were villose and regular, the reverse was scarlet at the edge of the colony, which was ca. 8.75 cm after 7 days of inoculation (Figure 1 I). Chlamydospores were aseptate, dark brown, smooth, in chains or solitary, ellipsoidal to ovoid, 4.8-9.6 × 4.8-11.1 μm (Figure 1 J). The pycnidia were produced on PDA and varied from 47.4 to 85.8 µm (mean 60.2 µm) × 38.6 to 66.8 μm (mean 49.7 μm) (n = 17) (Figure 1 K). Conidia were hyaline, unicellular, elliptical to ovoid, 4.3-6.4 µm (mean 5.1 µm) × 2.3-3.3 µm (mean 2.8 µm) (n = 52) (Figure 1 L). Pathogenicity tests of isolate XW-9 was carried out in the field. Ten leaves were wounded with a sterilized insect needle and inoculated with mycelium plugs (7-mm diameter). Non-colonized PDA plugs served as the negative controlIn addition, conidial suspensions (105 conidia/mL) of isolate XW-9 were sprayed on surface-sterilized leaves with a further ten leaves being sprayed with sterile water as the control. Symptoms described in this study appeared in 100% of the mycelium-inoculated leaves and more than 80% of the conidium-inoculated leaves after 7 days post-inoculation (Figure 1 B-E). No symptoms were seen in the controls (Figure 1 C). Three days after inoculation, brown spots resembling those observed in the field developed on the inoculated leaves, and some lesions turned into shot holes on the infected leaves (Figure 1 G & H). However, no symptoms were observed on the controls (Figure 1 F). The fungus was re-isolated from the margins of the leaf spots and labelled P-XW-9A. The gene regions for ITS, LSU, tub2, RPB2 and ACT of isolates XW-9 and P-XW-9A were amplified and sequenced. The sequences of rDNA-ITS, LSU, tub2, RPB2 and ACT of XW-9 were GenBank MW142397, MW130844, MW165322, MW446945 and MW165324, respectively and those of P-XW-9A were GenBank MW142398, MW130845, MW165323, MW446946 and MW165325, respectively (Lumbsch, et al. 2000; Aveskamp, et al. 2009; Hou et al. 2020). Phylogenetic analysis using concatenated sequences of ITS, LSU, RPB2, and tub2 showed that isolates XW-9 and P-XW-9A formed a single clade with the reference strain of E. poaceicola CBS 987.95 (Figure 2). Thus, XW-9 was identified as E. poaceicola based on its morphological and molecular characteristics. Significantly, the recovered isolate P-XW-9A also aligned with E. poaceicola fulfilling the criteria for Koch's Postulates. E. poaceicola was only reported as a fungal pathogen of Phyllostachys viridis in China (Liu et al. 2020). To our knowledge, this is the first report of leaf spot disease on camphor trees caused by E. poaceicola in China and our findings will be useful for its management.

Visual Light Leak in High-Frequency Electromagnetic Radiation Hole: A Photon-Electron Theory for Living Tissue for Explaining Myopia

If the frequency of the photon exceeds the threshold, the photon has enough energy to strike the electron away and forms a hole in living tissue include the eye. Longer time of high-frequency electromagnetic radiation will cause more holes and a larger radius of holes. Some visual light leak through the hole and cannot be refracted on the macula, this is myopia symptom of blurred vision, shortening the distance of the eye and the object will include more visual light into cornea and lens, this is myopia another symptom of nearsightedness. The longer eye axis is caused by strike of high energy photon. Blue light and X-ray from screen are two kinds of high-frequency electromagnetic radiation which can shot hole in eye and cause myopia. Healing the shot hole can cure myopia.

Euwallacea kuroshio (Kuroshio shot hole borer)

This datasheet on Euwallacea kuroshio covers Identity.

Identification of efficient attractant forthe management of shot hole borer, Xylosandrus compactus infesting coffee

Identification of efficient attractant forthe management of shot hole borer, Xylosandrus compactus infesting coffee

Biorational management of maize fall armyworm, Spodoptera frugiperda (J. E. Smith) (Lepidoptera: Noctuidae) using Bacillus thuringiensis (Berliner) enriched with chemical additives

An invasive pest, fall armyworm, Spodoptera frugiperda (J.E.Smith) (Lepidoptera: Noctuidae) attacks maize at every stage of development, from seedling emergence up to cob formation. Early instar larvae were seen mostly on leaves of maize with characteristics pin or shot hole symptoms. Later instar larvae were confined to deep whorls, leaving typically ragged like appearance and fed on the reproductive stage of the crop especially tassels and developing cobs resulting in quality and quantity loss of maize produce. The effect of commercially available Bacillus thuringiensis subsp. kurstaki product, Dipel® against the second instar larvae of Fall Armyworm (FAW )was not promising under laboratory conditions. Hence, an effort was made to add an adjuvant along with B. thuringiensis to increase the virulence of commercially available B. thuringiensis.The Laboratory bioassays with B. thuringiensis and seven chemical additives ( T1- Bt + Boric acid, T2- Bt + Zinc oxide, T3- Bt + Sodium nitrate, T4- Bt + Peptone, T5- Bt + Urea, T6- Bt + EDTA, T7- Bt + Citric acid &amp; T8- Bt alone T9- Control) were tested against second instar larvae of Spodoptera frugiperda larvae. The results showed that B. thuringiensis plus sodium nitrate (T3) promoted maximum mortality 82.2 per cent with a minimum LC50 value of 54.620 mg/l. Sodium nitrate boosted B. thuringiensis activity at a concentration of 0.05 per cent by 2.128-fold than B. thuringiensis alone. Overall, sodium nitrate improved the efficacy of B. thuringiensis spray at the maximum level followed by boric acid, urea, EDTA and peptone.

First Report of Shot-Hole on Flowering Cherry Caused by Burkholderia contaminans and Pseudomonas syringae pv. syringae.

Shot-hole disease (SH) is one of the most common and important diseases affecting flowering cherry (FC; Prunus × yedoensis Matsumura; Somei-yoshino) trees in South Korea every year, resulting in premature defoliation and reduced flowering in the following year. However, pathogens associated with the disease remain unknown, which has rendered disease management challenging. Here, the pathogens associated with SH, their biochemical characteristics, and their host range were elucidated. Detached-leaf and in planta assays revealed that two biofilm-forming bacteria-namely, Burkholderia contaminans and Pseudomonas syringae pv. syringae-caused SH of FC trees. These pathogens were recorded for the first time as the causes of SH of FC trees in South Korea. Additionally, the two pathogens induced similar disease symptoms in several stone fruit belonging to the genus Prunus, including peach (Prunus persica), plum (P. salicina), and apricot (P. mume), with peach being the most susceptible. These results indicate that B. contaminans and P. syringae pv. syringae caused SH on FC trees and presented a broad spectrum of hosts. Furthermore, Xanthomonas arboricola pv. pruni, the causative agent of leaf spot on stone fruit, incited brown spots and shot holes on FC leaves. Therefore, FC trees are susceptible to infections by various pathogenic bacteria, including B. contaminans, P. syringae pv. syringae, and X. arboricola pv. pruni. These findings will be of great importance as a reference for effective management of SH in the face of possible cross-infection between Prunus spp. in the future.

The polyphagous shot hole borer beetle: Current status of a perfect invader in South Africa

The polyphagous shot hole borer (PSHB) beetle is a recent invader in South Africa. Together with its fungal symbiont, Fusarium euwallaceae, it can rapidly kill highly susceptible host plants. Its impact is most profound in urban areas, but it has also been found infesting important forestry, agricultural crop and native species. Since its first detection in 2012, PSHB has spread to all but one province in the country. The beetle–fungus complex has several biological traits that enhance its anthropogenically mediated dispersal, establishment and survival in novel environments – factors that have likely facilitated its rapid spread across the country. We review the history of the PSHB invasion in South Africa, its taxonomic status and the reasons for its rapid spread. We highlight its potential impact and challenges for its management. Finally, we provide an updated distribution map and list of confirmed host plants in South Africa. Of the 130 plant species identified as hosts, 48 of these (19 indigenous and 29 introduced) are reproductive hosts able to maintain breeding PSHB populations. These reproductive hosts may succumb to beetle infestations and act as ‘pest-amplifiers’. The economic impact on urban forests, plantation forestry and agricultural crops may be severe, but the ecological impact of PSHB invasion in native ecosystems should not be underestimated.Significance: We provide an updated host list and distribution map for South Africa of the globally significant tree pest, the polyphagous shot hole borer (PSHB, Euwallacea fornicatus). The South African PSHB invasion represents the largest outbreak of this pest in its global invaded range. PSHB was confirmed to infest 130 plant species in urban, agricultural, and native ecosystems in South Africa, including 44 previously unreported hosts. Impact in South Africa is in its infancy but will likely be substantial to local economies and ecosystems. Mitigation has proven difficult, but numerous research projects have been initiated throughout the country.

The Control and Eradication of Invasive Species in Urban Areas in terms of South African Law: The City of Cape Town and the Polyphagous Shot Hole Borer Beetles

The introduction and prevalence of invasive species is an alarming reality in South Africa. The emergence of invasive species has resulted in harmful consequences on various levels and has adverse impacts on the environment and the economy. Hence, biological invasions demand attention. The control and eradication of invasive species can serve to minimise their adverse impact. In 2019 the South African National Biodiversity Institute highlighted the threats posed by biological invasions in South Africa and specifically identified Polyphagous Shot Hole Borer Beetles as a significant new invasive species in South Africa that has a demonstrable ongoing detrimental impact on varieties of trees. Polyphagous Shot Hole Borer Beetles have been detected in various urban areas in South Africa, including the City of Cape Town. This note briefly examines the control and eradication of invasive species in urban areas in terms of the South African legal framework, specifically against the backdrop of the emergence of the Polyphagous Shot Hole Borer Beetles in the City of Cape Town.

First report of Colletotrichum fioriniae causing anthracnose on mu oil tree in China.

Mu oil tree (Vernicia montana) is an economically important woody oil plant, which is widely distributed in southern China. In mid-May 2020, a leaf spot disease was observed on the leaves of mu oil tree in Taihe County in Jiangxi Province, China (26°55'25.55″N, 114°49'5.85″E). The disease incidence was estimated to be above 40%. Initial symptoms were circular red-brown spots which were 1-2 mm in diameter, then enlarged with red-brown center. In later stages, the spots coalesced and formed large patches, and subsequently red-brown centers of lesions gradually dried and fell out, forming a "shot hole" appearance. To identify the pathogen, diseased leaves were collected from Taihe County. Leaf tissues (5 × 5 mm) were cut from the margins of typical symptomatic lesions, surface- sterilized in 75% ethanol for 30 seconds and 3% sodium hypochlorite for 60 seconds, then rinsed with sterile distilled water three times. Leaf pieces were placed on potato dextrose agar (PDA; 1.5%, Difco-BD Diagnostics) and incubated at 25 °C in the dark. Pure cultures were obtained from individual conidia by recovering single spores. On PDA, colonies were initially white and cottony. The mycelia then became pinkish to deep-pink with time at the center on the front side and pink on the reverse side. Colonies produced pale orange conidial masses after 9 days. Conidia were fusiform with acute ends, smooth-walled, hyaline, and measured 3.6-5.5 × 8.1-14.5 µm (4.5 ± 0.5 × 10.6 ± 1.0 µm, n = 100). The morphological characteristics of the isolate matched the descriptions of Colletotrichum acutatum complex (Damm et al. 2012). For molecular identification, the internal transcribed spacer (ITS) region, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), chitin synthase (CHS-1), beta-tubulin 2 (TUB2), and actin (ACT) were sequenced using the primers ITS1/ITS4, GDF/GDR, CHS-79F/CHS-345R, T1/Bt2b, ACT-512F/ACT-783R, respectively (Weir et al. 2012). The obtained sequences were deposited into the GenBank [accession nos. MW584317 (ITS); MW656269 (GAPDH); MW656270 (TUB2); MW656268 (CHS-1); MW656267 (ACT)]. All the sequences showed 94 to 100% similarity with those of C. fioriniae. A neighbor-joining phylogenetic tree was generated by combining all the sequenced loci using MEGA7.0 (Kumar et al. 2016). The isolate TH-M4 clustered with C. fioriniae, having 99% bootstrap support. Base on the morphology and multi-gene phylogeny, isolate TH-M4 was identified as C. fioriniae (Damm et al. 2012). To confirm pathogenicity, 20 healthy leaves of 10 mu oil trees (3-year-old) grown outdoors were inoculated with a drop of spore suspension (106 conidia per mL) of the isolate TH-M4 in September 2020. Another 10 plants were inoculated with sterile water as the control. The leaves were wounded with a sterile toothpick. All the inoculated leaves were covered with black plastic bags to maintain humidity for 2 days. The pathogenicity test was repeated twice. The resulting symptoms were similar to those on the original infected plants, whereas the control leaves remained asymptomatic. The same fungus was re-isolated from the lesions on the inoculated plant, fulfilling Koch's postulates. C. fioriniae has been recorded as anthracnose pathogen on Mahonia aquifolium (Garibaldi et al. 2020), Paeonia lactiflora (Park et al. 2020), Solanum melongena (Xu et al. 2020), and Juglans regia (Varjas et al. 2020). To our knowledge, this is the first report of C. fioriniae associated with leaf spot disease on mu oil tree in China. This study provided crucial information for epidemiologic studies and appropriate control strategies for this oil plant disease.