The Arms Race Between KRAB-Zinc Finger Proteins and Endogenous Retroelements and Its Impact on Mammals.

Nearly half of the human genome consists of endogenous retroelements (EREs) and their genetic remnants, a small fraction of which carry the potential to propagate in the host genome, posing a threat to genome integrity and cell/organismal survival. The largest family of transcription factors in tetrapods, the Krüppel-associated box domain zinc finger proteins (KRAB-ZFPs), binds to specific EREs and represses their transcription. Since their first appearance over 400 million years ago, KRAB-ZFPs have undergone dramatic expansion and diversification in mammals, correlating with the invasions of new EREs. In this article we review our current understanding of the structure, function, and evolution of KRAB-ZFPs and discuss growing evidence that the arms race between KRAB-ZFPs and the EREs they target is a major driving force for the evolution of new traits in mammals, often accompanied by domestication of EREs themselves.

Stress-induced phase separation of ERES components into Sec bodies precedes ER exit inhibition in mammalian cells.

Phase separation of components of ER exit sites (ERES) into membraneless compartments, the Sec bodies, occurs in Drosophila cells upon exposure to specific cellular stressors, namely, salt stress and amino acid starvation, and their formation is linked to the early secretory pathway inhibition. Here, we show Sec bodies also form in secretory mammalian cells upon the same stress. These reversible and membraneless structures are positive for ERES components, including both Sec16A and Sec16B isoforms and COPII subunits. We find that Sec16A, but not Sec16B, is a driver for Sec body formation, and that the coalescence of ERES components into Sec bodies occurs by fusion. Finally, we show that the stress-induced coalescence of ERES components into Sec bodies precedes ER exit inhibition, leading to their progressive depletion from ERES that become non-functional. Stress relief causes an immediate dissolution of Sec bodies and the concomitant restoration of ER exit. We propose that the dynamic conversion between ERES and Sec body assembly, driven by Sec16A, regulates protein exit from the ER during stress and upon stress relief in mammalian cells, thus providing a conserved pro-survival mechanism in response to stress.

HTRA1-driven detachment of type I collagen from endoplasmic reticulum contributes to myocardial fibrosis in dilated cardiomyopathy.

BACKGROUND: The aberrant secretion and excessive deposition of type I collagen (Col1) are important factors in the pathogenesis of myocardial fibrosis in dilated cardiomyopathy (DCM). However, the precise molecular mechanisms underlying the synthesis and secretion of Col1 remain unclear. METHODS AND RESULTS: RNA-sequencing analysis revealed an increased HtrA serine peptidase 1 (HTRA1) expression in patients with DCM, which is strongly correlated with myocardial fibrosis. Consistent findings were observed in both human and mouse tissues by immunoblotting, quantitative reverse transcription polymerase chain reaction (qRT-PCR), immunohistochemistry, and immunofluorescence analyses. Pearson's analysis showed a markedly positive correlation between HTRA1 level and myocardial fibrosis indicators, including extracellular volume fraction (ECV), native T1, and late gadolinium enhancement (LGE), in patients with DCM. In vitro experiments showed that the suppression of HTRA1 inhibited the conversion of cardiac fibroblasts into myofibroblasts and decreased Col1 secretion. Further investigations identified the role of HTRA1 in promoting the formation of endoplasmic reticulum (ER) exit sites, which facilitated the transportation of Col1 from the ER to the Golgi apparatus, thereby increasing its secretion. Conversely, HTRA1 knockdown impeded the retention of Col1 in the ER, triggering ER stress and subsequent induction of ER autophagy to degrade misfolded Col1 and maintain ER homeostasis. In vivo experiments using adeno-associated virus-serotype 9-shHTRA1-green fluorescent protein (AAV9-shHTRA1-GFP) showed that HTRA1 knockdown effectively suppressed myocardial fibrosis and improved left ventricular function in mice with DCM. CONCLUSIONS: The findings of this study provide valuable insights regarding the treatment of DCM-associated myocardial fibrosis and highlight the therapeutic potential of targeting HTRA1-mediated collagen secretion.

TMED10 mediates the loading of neosynthesised Sonic Hedgehog in COPII vesicles for efficient secretion and signalling.

The morphogen Sonic Hedgehog (SHH) plays an important role in coordinating embryonic development. Short- and long-range SHH signalling occurs through a variety of membrane-associated and membrane-free forms. However, the molecular mechanisms that govern the early events of the trafficking of neosynthesised SHH in mammalian cells are still poorly understood. Here, we employed the retention using selective hooks (RUSH) system to show that newly-synthesised SHH is trafficked through the classical biosynthetic secretory pathway, using TMED10 as an endoplasmic reticulum (ER) cargo receptor for efficient ER-to-Golgi transport and Rab6 vesicles for Golgi-to-cell surface trafficking. TMED10 and SHH colocalized at ER exit sites (ERES), and TMED10 depletion significantly delays SHH loading onto ERES and subsequent exit leading to significant SHH release defects. Finally, we utilised the Drosophila wing imaginal disc model to demonstrate that the homologue of TMED10, Baiser (Bai), participates in Hedgehog (Hh) secretion and signalling in vivo. In conclusion, our work highlights the role of TMED10 in cargo-specific egress from the ER and sheds light on novel important partners of neosynthesised SHH secretion with potential impact on embryonic development.

First Report of Leaf Blight of Osmanthus fragrans Caused by Diaporthe eres in China.

Osmanthus fragrans is an evergreen garden tree species, with high ecological, social, and economic benefits (Lan et al. 2023), which is widely planted in Guizhou Province. From late April to June 2023, a leaf blight disease was observed on O. fragrans in a bauxite mining area in Qingzhen City, with an incidence of ~50%. Symptoms first appeared at the leaf tip or margin, as irregular brown spots, which gradually coalesced into dark brown patches until the leaves withered and fell off. Symptomatic leaves were collected and surface disinfected with 2% NaClO for 30 s, 75% ethanol for 30 s, rinsed 3 times in sterile ddH2O, air-dried and placed on potato dextrose agar (PDA) medium and incubated at 25°C for 7 d. Fungal colonies on PDA of 9 similar obtained isolates were white, with at least one concentric ring. The reverse was light yellow and gradually turned brown. At 12 d, the pycnidia on PDA was gray to black, spherical or conical, with a diameter of 305.15 µm (n=20). The conidial horns oozed out from pycnidia after 25 d of incubation on Pinus massoniana needles. The alpha conidia were unicellular, fusiform, hyaline, had a guttule at each end, and measured 6.24 ± 0.10 µm × 2.48 ± 0.04 µm (n=50). No beta or gamma conidia were observed. The morphological characteristics were likely to Diaporthe spp. (Gomes et al. 2013). DNA of isolates GH02, GH06 and GH08 was extracted. The internal transcribed spacer region (ITS) and partial sequences of translation elongation factor 1-alpha (TEF1-α), calmodulin (CAL), beta-tubulin (TUB2), and histone H3 (HIS) genes were amplified with primers ITS1/ITS4 (White et al. 1990), EF1-728F/EF1-986R, CAL228F/CAL737R (Carbone and Kohn, 1999), ßt2a/ßt2b and CYLH3F/H3-1b (Crous et al. 2004; Glass and Donaldson, 1995), respectively. The sequences of ITS, TEF-1α, TUB2, CAL and HIS were deposited in GenBank (GH02: PP813499, PP813844, PP813846, PP813848 and PP813850; GH06: PP813500, PP813845, PP813847, PP813849 and PP813851; GH08: PP507168 and PP529956 to PP529959). BLAST results showed the sequences of GH08 were highly identical to sequences of Phomopsis mahothocarpi (NR147522 [ITS], 527/530), P. mahothocarpi (MW700277 [TEF-1α], 367/372), D. eres (OR885862 [TUB], 513/513), D. celeris (ON221721 [CAL], 484/486), and D. eres (OP968956 [HIS], 477/477). A phylogenetic tree constructed with MEGA X using Neighbor-Joining algorithm (Felsenstein, 1985) indicated the isolate GH02, GH06 and GH08 separated from D. eres CBS 297.77 previously reported from O. aquifolium in Netherlands, as well as D. osmanthi and D. fusicola from O. fragrans in China (Gomes et al. 2013; Long et al. 2019; Si et al. 2021). Based on these results, the three isolates were identified as D. eres (Chaisiri et al., 2021). The isolate GH08 was deposited in the Forest Protection Laboratory, Guizhou University. To confirm pathogenicity, spore suspensions (1×105 spores/mL) of GH08 were sprayed on healthy detached leaves (n=10) and leaves of 3-year-old potted O. fragrans seedlings (n=8). An equal volume of sterile water was sprayed for the control. Then they were placed at 20°C and 70-80% RH. Similar leaf blight symptoms appeared after 5 and 15d on the inoculated leaves and seedlings, respectively. The re-isolated fungus, was identical to D. eres based on morphological and molecular analysis, thus fulfilling Koch's postulates. To our knowledge, this is the first report of D. eres causing leaf blight of O. fragrans in China, supporting a basis for developing effective methods to manage this disease.

First report of Diaporthe eres causing leaf spot on Rosa roxburghii Tratt in Guizhou Province, China.

Rosa roxburghii Tratt is a plant from the Rosaceae family whose fruits are rich in vitamins, dietary fiber, flavonoids, phenolic acids, and other active components (Jiang, et al. 2024). In July 2023, about R. roxburghii 500 plants were investigated in a field of 6000 m2 in Guiding County (107°14'E, 26°45'N), Guizhou province, China, and the results showed a leaf spot incidence of s 20 to 30%. . The affected leaves had irregular, black lesions with a clear blackish brown boundary and faint black conidiomata in a brown center. Fifteen symptomatic leaves were collected from 10 plants washed with sterile distilled water, and 5 × 5 mm pieces of the infected tissues were cut. After surface sterilization for30 s with 75% ethanol, 2 min with 3% NaOCl, three washes in sterilized distilled water, the leaf pieces were dried and placed on potato dextrose agar (PDA) and incubated at 25℃ for 5 days. Three isolates (H3-Y-1-1, H3-Y-1-2, H3-Y-1-3) with identical morphology were obtained, and the isolate H3-Y-1-1was selected for further study. The colonies on PDA exhibited irregular growth patterns, with white felty aerial mycelium on the upper surface, and white mycelium on the lower surface. Conidiomata were irregularly distributed over the agar surface. The isolate H3-Y-1-1 produced darkly pigmented pycnidia on PDA after 30 days and oozed milky mucilaginous drops. The fungus produced two types of conidia, α and ß. Regular α conidia were 4.74 - 5.96 × 1.52 - 2.24 µm (n = 50), hyaline, elongated, biguttulate and non-septate. Beta conidia were 20.13 - 25.74 × 0.86 - 1.29 µm (n = 50), aseptate, hyaline, smooth, spindle shaped, slightly curved to bent. The morphological features were consistent with the description of Diaporthe eres (Pereira, et al. 2022). The pathogen was confirmed to be D. eres by amplification and sequencing of the internal transcribed spacer region (ITS), the partial ß-tubulin (TUB), the partial translation elongation factor 1-alpha (TEF) genes using primers ITS1/ITS4, Bt-2a/Bt-2b, EF1-728F/EF1-986R, respectively. Sequences from PCR amplification were deposited in GenBank with accession numbers PP411998 (ITS), PP502153 (TUB), PP502156 (TEF). BLAST searches of the sequences revealed (96%) (500/523nt), 97% (479/494 nt) and 99% (334/338 nt) homology with those of D. eres CBS 138594 from GenBank (OM698848, OM752196 and OM752197), respectively. Phylogenetic analysis using maximum-likelihood and Bayesian methods placed the isolate H3-Y-1-1 in a well-supported cluster with D. eres CBS 101742. The pathogen was thus identified as D. eres based on the morphological characterization and molecular analyses (Feng, et al. 2013; Tao, et al. 2020). To assess its pathogenicity, healthy R. roxburghii potted plants were inoculated with H3-Y-1-1 spore suspensions. Symptomatic leaves mirroring field symptoms were observed after XX days of incubations at XX°C, while control plants exhibited no symptoms. Diaporthe eres was consistently reisolated from the infected leaves showing brown irregular or round lesions at the initial stage of the disease, expanding and become more irregular over time ultimately causing leaf curling and plant death. To our knowledge, this is the first report of leaf spot on R. roxburghii caused by D. eres in China. The disease may become a serious threat to fruit of R. roxburghii production in China. Therefore, detection of this pathogen is very important to ensure timely disease management.

First report of Diaporthe eres causing leaf spot on Rhododendron latoucheae Franch. in China.

Rhododendron latoucheae Franch. is an evergreen shrub with charming fragrance and large and abundant flowers that make it highly attractive as an ornamental species. The species is distribution in southwest China covers several different habitats and environments (Zhang, et al. 2022). From May to July in 2023, symptoms of leaf spot were observed on R. latoucheae over a wide portion of the Baili Azalea Forest Area (27°10' to 27°20'N, 105°04' to 106°04'E), Guizhou Province, China. About 500 plants were surveyed, and the incidence of leaf spot on R. latoucheae leaves was 12%, significantly reducing their ornamental and economic value. The affected leaves had irregular, grey white lesions with a clear blackish brown boundary and faint black conidiomata in a brown center. To isolate the pathogen, 15 symptomatic leaves were collected from 10 plants. A few black dots were picked from the lesions with a sterilized needle, plated on water agar, and incubated at 25°C for 24 h to observe spore germination (Choi et al. 1999). Then the germinated spores were transferred onto PDA for further purification and morphological observation. Three single-spore isolates (GULJ1-L7, GULJ1-L8, and GULJ1-L9) identical in morphology were obtained. The isolate GULJ 1-L7 was used for further study. Colonies on PDA irregular grew white felty aerial mycelium, becoming white felted aerial mycelium in the centre and grey-brown mycelium at the marginal area on the upper surface, while the lower surface presents alternating white, tan and taupe. Colony with conidiomata irregularly distributed over agar surface. In the representative isolate, darkly pigmented pycnidia (flask-shaped) were produced over the colony surface on PDA after about 30 days, and oozed milky or yellowish mucilaginous drops. The fungus produced two types of conidia, α and ß. Regular α conidia were 5.15-10.29 × 1.54-3.33 µm (n = 50), hyaline, elongated, biguttulate and non-septate. Beta conidia were 20.34-31.91 × 1.01-1.90 µm (n = 50), aseptate, hyaline, smooth, spindle shaped, slightly curved to bent. The morphological features were consistent with the description of Diaporthe eres (Pereira, et al. 2022). The pathogen was confirmed to be D. eres by amplification and sequencing of the internal transcribed spacer region (ITS), the partial ß-tubulin (TUB), the partial translation elongation factor 1-alpha (TEF) genes and the calmodulin (CAL) using primers ITS1/ITS4, Bt-2a/Bt-2b, EF1-728F/EF1-986R, and CAL-228F/CAL-737R, respectively (Tao et al. 2020). Sequences from PCR amplification were deposited in GenBank with accession numbers OR740563 (ITS), OR754301 (TUB), OR754298 (TEF), and OR754295 (CAL) respectively. BLAST searches of the sequences revealed 99.07% (533/538 nt), 100% (490/490 nt), 99.69% (317/318 nt) and 98.95% (376/380 nt) homology with those of D. eres AR5193T from GenBank (KJ210529.1, KJ420799.1, KJ210550.1 and KJ434999.1), respectively. Phylogenetic analysis (MEGA 7.0) using the maximum-likelihood method placed the isolate GULJ1-L7 in a well-supported cluster with D. eres CBS 138694T. The pathogen was thus identified as D. eres based on the morphological characterization and molecular analyses (Feng, et al. 2013; Tao, et al. 2020). The pathogenicity of GULJ1-L7 was tested through a pot assay. Due to the difficulty of artificial planting wild R. latoucheae, we conducted a pot essay to detect the pathogenicity of GULJ1-L7 using a closely related Rhododendron delavayi Franch. Ten healthy R. delavayi plants were scratched with a sterilized needle (0.45 mm in diameter) on three leaves per plant. Plants were inoculated by spraying α and ß spore mixture suspension (106 spores ml-1) of GULJ1-L7 onto leaves until runoff, and the control leaves were sprayed with sterile water. The plants were maintained at 25°C and 75% relative humidity in a growth chamber. The pathogenicity test was repeated three times. After 14 days, the treated leaves developed brown lesions similar to those in the field, whereas the control had no symptoms. The same fungus was reisolated from the infected leaves and identified based on a morphological characterization and molecular analyses. These results fulfilled Koch's postulates. To our knowledge, this is the first report of leaf spot on R. latoucheae caused by D. eres in China. The fungal pathogen identification will provide valuable information for prevention and management of leaf spot disease associated with R. latoucheae.

Pharmacological chaperone-rescued cystic fibrosis CFTR-F508del mutant overcomes PRAF2-gated access to endoplasmic reticulum exit sites.

The endoplasmic reticulum exit of some polytopic plasma membrane proteins (PMPs) is controlled by arginin-based retention motifs. PRAF2, a gatekeeper which recognizes these motifs, was shown to retain the GABAB-receptor GB1 subunit in the ER. We report that PRAF2 can interact on a stoichiometric basis with both wild type and mutant F508del Cystic Fibrosis (CF) Transmembrane Conductance Regulator (CFTR), preventing the access of newly synthesized cargo to ER exit sites. Because of its lower abundance, compared to wild-type CFTR, CFTR-F508del recruitment into COPII vesicles is suppressed by the ER-resident PRAF2. We also demonstrate that some pharmacological chaperones that efficiently rescue CFTR-F508del loss of function in CF patients target CFTR-F508del retention by PRAF2 operating with various mechanisms. Our findings open new therapeutic perspectives for diseases caused by the impaired cell surface trafficking of mutant PMPs, which contain RXR-based retention motifs that might be recognized by PRAF2.

Molecular Characterization and Pathogenicity of Diaporthe Species Causing Nut Rot of Hazelnut in Italy.

Hazelnut (Corylus avellana), a nut crop that is rapidly expanding worldwide, is endangered by a rot. Nut rot results in hazelnut defects. A survey was conducted in north-western Italy during 2020 and 2021 to identify the causal agents of hazelnut rots. Typical symptoms of black rot, mold, and necrotic spots were observed on hazelnut nuts. The prevalent fungi isolated from symptomatic hazelnut kernels were Diaporthe spp. (38%), Botryosphaeria dothidea (26%), Diplodia seriata (14%), and other fungal genera with less frequent occurrences. Among 161 isolated Diaporthe spp., 40 were selected for further analysis. Based on morphological characterization and multi-locus phylogenetic analysis of the ITS, tef1- α, and tub2, seven Diaporthe species were identified as D. eres, D. foeniculina, D. novem, D. oncostoma, D. ravennica, D. rudis, and D. sojae. D. eres was the main species isolated from hazelnut rots, in particular from moldy nuts. Pathogenicity test performed on hazelnut nuts 'Tonda Gentile del Piemonte' using a mycelium plug showed that all the Diaporthe isolates were pathogenic on their original host. To our knowledge, this work is the first report of D. novem, D. oncostoma and D. ravennica on hazelnut nuts worldwide. Diaporthe foeniculina, D. rudis, and D. sojae were reported for the first time as agents of hazelnut nut rot in Italy. Future studies should focus on the comprehension of epidemiology and climatic conditions favoring the development of Diaporthe spp. on hazelnut. Prevention and control measures should target D. eres, representing the main causal agents responsible for defects and nut rot of hazelnuts in Italy.

Control of CCR5 Cell-Surface Targeting by the PRAF2 Gatekeeper.

The cell-surface targeting of neo-synthesized G protein-coupled receptors (GPCRs) involves the recruitment of receptors into COPII vesicles budding at endoplasmic reticulum exit sites (ERESs). This process is regulated for some GPCRs by escort proteins, which facilitate their export, or by gatekeepers that retain the receptors in the ER. PRAF2, an ER-resident four trans- membrane domain protein with cytoplasmic extremities, operates as a gatekeeper for the GB1 protomer of the heterodimeric GABAB receptor, interacting with a tandem di-leucine/RXR retention motif in the carboxyterminal tail of GB1. PRAF2 was also reported to interact in a two-hybrid screen with a peptide corresponding to the carboxyterminal tail of the chemokine receptor CCR5 despite the absence of RXR motifs in its sequence. Using a bioluminescence resonance energy transfer (BRET)-based subcellular localization system, we found that PRAF2 inhibits, in a concentration-dependent manner, the plasma membrane export of CCR5. BRET-based proximity assays and Co-IP experiments demonstrated that PRAF2/CCR5 interaction does not require the presence of a receptor carboxyterminal tail and involves instead the transmembrane domains of both proteins. The mutation of the potential di-leucine/RXR motif contained in the third intracellular loop of CCR5 does not affect PRAF2-mediated retention. It instead impairs the cell-surface export of CCR5 by inhibiting CCR5's interaction with its private escort protein, CD4. PRAF2 and CD4 thus display opposite roles on the cell-surface export of CCR5, with PRAF2 inhibiting and CD4 promoting this process, likely operating at the level of CCR5 recruitment into COPII vesicles, which leave the ER.

Pioneering Metabolomic Studies on Diaporthe eres Species Complex from Fruit Trees in the South-Eastern Poland.

Fungi from the genus Diaporthe have been reported as plant pathogens, endophytes, and saprophytes on a wide range of host plants worldwide. Their precise identification is problematic since many Diaporthe species can colonize a single host plant, whereas the same Diaporthe species can inhabit many hosts. Recently, Diaporthe has been proven to be a rich source of bioactive secondary metabolites. In our initial study, 40 Diaporthe isolates were analyzed for their metabolite production. A total of 153 compounds were identified based on their spectroscopic properties-Ultraviolet-visible and mass spectrometry. From these, 43 fungal metabolites were recognized as potential chemotaxonomic markers, mostly belonging to the drimane sesquiterpenoid-phthalide hybrid class. This group included mainly phytotoxic compounds such as cyclopaldic acid, altiloxin A, B, and their derivatives. To the best of our knowledge, this is the first report on the metabolomic studies on Diaporthe eres species complex from fruit trees in the South-Eastern Poland. The results from our study may provide the basis for the future research on the isolation of identified metabolites and on their bioactive potential for agricultural applications as biopesticides or biofertilizers.

Vesicular and uncoated Rab1-dependent cargo carriers facilitate ER to Golgi transport.

Secretory cargo is recognized, concentrated and trafficked from endoplasmic reticulum (ER) exit sites (ERES) to the Golgi. Cargo export from the ER begins when a series of highly conserved COPII coat proteins accumulate at the ER and regulate the formation of cargo-loaded COPII vesicles. In animal cells, capturing live de novo cargo trafficking past this point is challenging; it has been difficult to discriminate whether cargo is trafficked to the Golgi in a COPII-coated vesicle. Here, we describe a recently developed live-cell cargo export system that can be synchronously released from ERES to illustrate de novo trafficking in animal cells. We found that components of the COPII coat remain associated with the ERES while cargo is extruded into COPII-uncoated, non-ER associated, Rab1 (herein referring to Rab1a or Rab1b)-dependent carriers. Our data suggest that, in animal cells, COPII coat components remain stably associated with the ER at exit sites to generate a specialized compartment, but once cargo is sorted and organized, Rab1 labels these export carriers and facilitates efficient forward trafficking.This article has an associated First Person interview with the first author of the paper.

Diversity of Botryosphaeriaceae and Diaporthe Species Associated with Postharvest Apple Fruit Decay in Serbia.

Family Botryosphaeriaceae and the genus Diaporthe (family Diaporthaceae) represent diverse groups of plant pathogens, which include causal agents of leaf spot, shoot blight, branch and stem cankers, dieback, and pre- and postharvest apple fruit decay. Apple fruit with symptoms of light to dark brown decay were collected during and after harvest from 2016 to 2018. Thirty selected isolates, on which pathogenicity was confirmed, were identified and characterized based on multilocus phylogeny and morphology. Five species from the family Botryosphaeriaceae and two from the genus Diaporthe (fam. Diaporthaceae) were discovered. The most commonly isolated was Diplodia seriata followed by Botryosphaeria dothidea. In this work, Diaporthe rudis is described as a new postharvest pathogen of apple fruit. Diplodia bulgarica, Diplodia sapinea, Neofusicoccum yunnanense, and Diaporthe eres are initially described as postharvest apple and D. sapinea as postharvest quince and medlar fruit pathogens in Serbia. Because species of the family Botryosphaeriaceae and the genus Diaporthe are known to cause other diseases on their hosts, have an endophytic nature, and have a wide host range, findings from this study imply that they may become a new challenge for successful fruit production.

First report of Diaporthe eres causing leaf spot disease on Machilus thunbergii in Korea.

Machilus thunbergii (Japanese bay tree) is native to warm temperate and subtropical regions in East Asia such as China, Japan, Korea, Taiwan, and Vietnam (Wu et al., 2006). This tree is used for landscape trees, windbreaks, and furniture because the wood is hard and dense (Hong et al., 2016). In May 2020, a leaf spot disease was observed on M. thunbergii in an arboretum on Wando Island, Korea. Among 25 trees surveyed in the arboretum, 7 trees showed 5 to 30% leaf spot disease. Symptoms consisted of gray and dry leaf spots up to approximately one to two centimeters in diameter, surrounded by a deep black margin. Leaf samples containing lesions were collected from the seven diseased trees. Pieces of leaf tissue (5mm × 5mm) were cut from the lesion margins and surface disinfected with 1% sodium hypochlorite (NaOCl) for 1 min and rinsed with sterile distilled water three times, patted dry on sterile paper towel and placed on Potato Dextrose Agar (PDA) in Petri dishes. From the cultures, ten fungal isolates were obtained and two representative isolates (CMML20-5 and CMML20-6) were stored at the Molecular Microbiology Laboratory, Chonnam National University, Gwangju, Korea. Colony morphology of the two isolates on PDA was observed after 7 days at 25°C in the dark. Conidiomata were induced after 7days in a 14h-10h light-dark condition using sufficiently grown mycelium in PDA, and both alpha and beta conidia were observed. Alpha conidia were 7.6 ± 0.9 × 2.8 ± 0.4 µm (n = 30), fusiform, aseptate, and hyaline. Beta conidia were 28.1 ± 3.6 × 2.7 ± 0.4 µm (n = 30), aseptate, hyaline, linear to hooked. Genomic DNA of the two isolates was extracted using the CTAB DNA extraction method (Cubero et al., 1999), followed by PCR using primer sets of the internal transcribed spacer (ITS1/ITS4) (White et al., 1990), elongation factor 1-α (EF1-728F/EF1-986R), calmodulin (CAL228F/CAL737R) (Carbone and Kohn, 1999), and TUB2 (Bt2a/Bt2b) (Glass and Donaldson 1995). PCR products were sequenced and analyzed to confirm species identity. The obtained sequences were deposited in GenBank (accession numbers OM049469, OM049470 for ITS, OM069429, OM069430 for EF1-α, OP130141, OP130142 for CAL, and OP130139, OP130140 for TUB2). BLASTn search analyses for ITS, EF1-α, CAL, and TUB2 sequences of two isolates selected resulted in near identical match (>97% for ITS, 100% for EF1-α, >99% for CAL, and >96% for TUB2) to sequences of Diaporthe eres strain AR4346 (=Phomopsis fukushii) (JQ807429 for ITS, JQ807355 for EF1-α, KJ435003 for CAL, and KJ420823 for TUB2). Phylogenetic analysis using maximum likelihood indicated that the two isolates grouped with reference strains (AR4346, AR4349, and AR4363) of D. eres with 76% bootstrap support. Based on morphological and phylogenetic analyses, the two isolates characterized in this study are members of the Diaporthe eres species complex as described by Udayanga et at. 2014. Pathogenicity tests were conducted using both detached leaf and whole plant assays. Mycelial PDA plugs (5-mm in diameter) or 10µl of 106 conidia suspensions were inoculated on detached leaves of M. thunbergii from 2-year-old trees and placed in 90 mm Petri-dishes containing wet filter papers or water agar medium. Mock inoculated controls used water in place of conidial suspensions. The plates were sealed with Parafilm and incubated at 25°C in the dark. Two year old M. thunbergii trees were inoculated with wet mycelia (1.5g) that was ground with a homogenizer and mixed with 50ml of sterile water and sprayed onto wounded leaves and stems with a needle. Mock inoculated controls were sprayed with water only. The inoculated seedlings were placed in plastic containers at 25 to 30°C to maintain high humidity. The pathogenicity tests were repeated three times with three replications. In detached leaves, symptoms of black spots were observed 6 days after mycelial plug inoculation and 20 days after conidia inoculation. In whole plants, typical symptoms were observed 9 days after inoculation. Symptoms were not observed on the control leaves and plants. Diaporthe eres was re-isolated from the inoculated leaf and whole plants and morphologically identified, fulfilling Koch's postulates. Diaporthe eres has been reported to cause a leaf spot on Photinia × fraseri 'Red Robin' in China (Song et al. 2019). To our knowledge, this is the first report of leaf spot disease caused by Diaporthe eres on Japanese bay tree (Machilus thunbergii) in Korea. It is expected that use of this tree will expand given its utility, however infection with D. eres can cause serious diseases to the leaves and stems. Therefore, further studies on disease management are needed.

First Report of Diaporthe eres Causing Leaf Spot on Pseudocydonia sinensis in China.

Pseudocydonia sinensis is a Chinese ornamental plant with great landscaping value. Its fruit is additionally used for medicinal purposes (Lim 2012). In June 2020, a leaf spot disease was observed in the campus of Nanjing Forestry University (32°04'34.53″N 118°48'42.06″E). The symptoms began with irregular red-brown spots, which gradually enlarged, extended and overlapped, with an incidence of 85% (29/34 trees). Pieces of leaf tissue (3 to 4 mm²) from the lesion margins were surface-sterilized with 75% ethanol for 30 s and 1% NaClO for 90 s. Subsequently, the tissues were rinsed with sterile H2O, placed on potato dextrose agar (PDA) medium and incubated at 25℃ for 5 days. The same fungus was isolated from 90% of tissues. Pure cultures were obtained by monosporic isolation.The representative isolate NJMG 5-7 was used for morphological and molecular characterization. The growing fungal colony on PDA was initially white, but gradually turned grey. Pycnidia formation was observed on PDA supplemented with alfalfa stems. The pycnidia produced two different types of conidia, α and ß, which ooze out in yellow creamy mucilaginous masses. Conidiophores were hyaline, cylindrical and smooth, 16.8 to 33.1 × 1.5 to 2.6 µm (n=30). Conidiogenous cells were 13.6 to 29.3 × 1.5 to 2.7 µm (n=30). The α-conidia were, unicellular, hyaline elliptical or fusiform, bi-guttulate, 6.5 to 9.2 × 1.8 to 3.3 µm (n = 50). The ß-conidia were hyaline, aseptate, without guttules, filiform, curved, with obtuse ends, 12.5 to 25 × 1.0 to 1.8 µm (n = 50). To verify species identity, the partial sequences of the internal transcribed spacer (ITS) region, and calmodulin (CAL), translation elongation factor 1 alpha (EF1-a), and beta-tubulin genes (TUB) were amplified from isolate NJMG 5-7 with primers ITS1/ITS4 (White et al. 1990), CAL-228F/CAL-737R (Carbone & Kohn 1999), EF1-728F/EF1-986R (Carbone and Kohn 1999), and Bt2a/Bt2b (Glass and Donaldson 1995), respectively. The sequences were deposited in GenBank (OP223050 for ITS, OP252809 for CAL, OP252807 for EF1-a, and OP252808 for TUB). A BLAST search of GenBank showed that ITS, CAL, EF1-a and TUB sequences of NJMG 5-7 were similar to those of D. eres CBS 138594 (99% identity), AR5193 (99%), AR5193 (99%) and MG281193 (100%), respectively. The morphological and molecular results identified the isolate as D. eres (Feng et al. 2015). To fulfill Koch's postulates, a pathogenicity test was conducted using three P. sinensis plants. Six leaves from each tree were wounded and inoculated with mycelial plugs (about 4 mm in diameter) of D. eres from a 3-day-old culture grown on PDA. Inoculations with sterile PDA plugs on different leaves of the same tree were used as controls. All inoculated leaves were enclosed in plastic bags together with a wet cotton ball inside. Sterile H2O was sprayed into the plastic bags to keep moisture conditions. Five days later, all inoculated points showed lesions similar to those previously observed in the field, whereas controls were asymptomatic. The pathogen was successfully reisolated from the inoculated symptomatic parts on PDA and identified from its morphology, thus fulfilling Koch's postulates. This fungus can cause a variety of diseases. To our knowledge, this is the first report of D. eres causing leaf spots on P. sinensis in the world. These findings provide a foundation for future studies on the epidemiology and control of this newly emerging disease.

Molecular and Biological Characterization of Two New Species Causing Peach Shoot Blight in China.

Peach shoot blight (PSB), which kills shoots, newly sprouted leaf buds, and peach fruits, has gradually increased over the last 10 years and resulted in 30 to 50% of total production loss of the peach industry in China. Phomopsis amygdali has been identified as the common causal agent of this disease. In this study, two new species, Phomopsis liquidambaris (strain JW18-2) and Diaporthe eres (strain JH18-2), were also pathogens causing PSB, as determined through molecular phylogenetic analysis based on the sequences of the internal transcribed spacer (ITS) region, translation elongation factor 1-α (EF1-α) and beta-tubulin (TUB), and colony and conidial morphological characteristics. Biological phenotypic analysis showed that the colony growth rate of strain JW18-2 was faster than that of strains JH18-2 and ZN32 (one of the P. amygdali strains that we previously found and identified). All three strains produced α-conidia; however, JW18-2 could not produce ß-conidia on alfalfa decoction and Czapek media, and the ß-conidia produced by strain JH18-2 were shorter in length and thicker in width than those produced by strain ZN32. Pathogenicity tests showed that JW18-2 presented the strongest pathogenicity for peach fruits and twigs and was followed by strains JH18-2 and ZN32. The results shed light on the etiology of PSB and provide a warning that P. liquidambaris or D. eres might develop into dominant species after a few years while also potentially benefitting the development of effective disease control management strategies.

First Report of Diaporthe eres Causing Leaf Spot of Viburnum odoratissimum var. awabuki in China.

Viburnum odoratissimum var. awabuki (K. Koch) Zabel ex Rumpl. is an evergreen tree, used as a landscape plant in China. In June 2019, a foliar disease of ~60% incidence was observed on V. odoratissimum var. awabuki at the campus of Nanjing Forestry University, Jiangsu, China. The symptoms were initially irregular small red-brown spots, later enlarged and became brown to black. Small pieces of tissue (3 to 4 mm2) cut from lesion margins were surfaced sterilized in 75% ethanol for 30 s and 1.5% NaClO for 60 s, then rinsed in sterile water and placed on potato dextrose agar (PDA) at 25℃. Pure cultures were obtained from the tip of hyphae. Using the standard phytopathological procedure, two representative isolates (SH161 and SH181) were obtained and deposited at Nanjing Forestry University. The colony on PDA was white with aerial mycelium, radiate, and the reverse was white. Black pycnidia developed on the sterilized alfalfa stems at 25°C with a 14/10 h light/dark cycle for 20 days. Conidiophores were hyaline, branched, straight to sinuous, 9.4 to 26.0 × 1.0 to 2.5 µm (n=30). Conidiogenous cells were 2.1 to 15.1 × 0.9 to 2.5 µm (n=30). Alpha conidia were 7.4 ± 0.6 × 2.0 ± 0.2 µm (n=50), hyaline, ellipsoidal to lanceolate. Beta conidia were 29.5 ± 1.8 × 1.1 ± 0.1 µm (n=30), aseptate, hyaline, smooth, curved to hooked. Morphological features of two isolates matched those of Diaporthe spp.. DNA of two isolates was extracted and the internal transcribed spacer region (ITS), partial translation elongation factor 1-alpha (TEF1-α), calmodulin (CAL), beta-tubulin (TUB), and histone H3 (HIS) genes were amplified with primers ITS1/ITS4, EF1-728F/EF1-986R, CAL228F/CAL737R, ßt2a/ßt2b and CYLH3F/H3-1b. The sequences were deposited into GenBank (Accession Nos. for isolate SH161: OK326730 for ITS, OK413403 to OK413406 for TUB, CAL, HIS and TEF1-α; and isolate SH181: OK331347 for ITS, OK413407 to OK413410 for TUB, CAL, HIS, and TEF1-α). BLAST search of SH161 showed high similarities with sequences of Diaporthe eres (AR5193) [KJ210529 (ITS), Identities = 438/512, (94%); KJ420850 (HIS), Identities = 466/472, (99%); KJ210550 (TEF1-α), Identities = 345/350, (99%); KJ434999 (CAL), Identities = 344/345, (99%); KJ420799 (TUB), Identities = 508/517, (98%)]. BLAST results of SH181 are listed in Supplementary Table 1. Maximum likelihood and Bayesian posterior probability analyses using IQtree v. 1.6.8 and MrBayes v. 3.2.6 with the concatenated sequences placed SH161 and SH181 in the clade of D. eres. Based on the multi-locus phylogeny and morphology, two isolates were identified as D. eres. The pathogenicity was tested on 1-yr-old cuttings of V. odoratissimum var. awabuki in the greenhouse. Healthy leaves were wounded with a sterile needle, then inoculated with 5-mm plugs from the edge of two isolates cultures. The PDA plugs were used for controls. Three plants were used for each treatment, and three leaves of each plant were inoculated. Each plant was covered with a plastic bag, and sterilized water was sprayed into the bags bidaily to maintain humidity and kept in a greenhouse at the day/night temperatures at 25 ± 2°C/16 ± 2°C. Three days after inoculation, the inoculated leaves appeared lesions similar to those in the field. The controls remained healthy. Diaporthe eres was reisolated from inoculated leaves. No fungus was isolated from controls. Diaporthe eres was reported from Viburnum lantana in Austria. Also, it was reported from V. odoratissimum and V. tinus in Ukraine. This is the first report of D. eres causing V. odoratissimum var. awabuki leaf spots in China. This finding will provide an effective basis for developing control strategies for the disease.

First Report of Diaporthe eres and D. unshiuensis causing Leaf Spots on Sapindus mukorossi in China.

Sapindus mukorossi Gaertn., commonly known as soapberry, is widely cultivated as a landscaping tree in Southern China. In June 2019, a foliar disease with an incidence of ∼60% occurred on trees was observed in the soapberry germplasm repository, Jianning, Sanming, Fujian, China. The symptoms initially appeared as irregular small yellow spots, while the center of the lesions became dark brown with time. Fragments (size 3 to 4 mm2) taken from lesion margins were sterilized and cultured based on Wang et al. Two isolates (FJ1 and FJ21) were obtained with the following morphological characteristics on PDA, (1) FJ1: Conidiogenous cells were 9.7 to 25.0 × 1.5 to 2.2 µm (n=20). Alpha conidia were 6.1 to 8.3 × 2.2 to 3.0 µm (n=30), aseptate, hyaline, smooth, ellipsoidal. Beta conidia were 28.3 to 38.2 × 1.3 to 1.7 µm (n=30), hyaline, smooth, curved to hooked. Conidial drops were milky colored; (2) FJ21: Pycnidia were dark brown, 280 to 843 µm (n=30) in diam., globose, or irregular on alfalfa stems. Conidiophores were hyaline, cylindrical, smooth, and slightly tapered to the apex, 17.4 to 35.4 × 1.5 to 2.6 µm (n=20). Conidiogenous cells were 14.7 to 29.7 × 1.4 to 2.6 µm (n=20). Alpha conidia were 5.6 to 7.1 × 2.4 to 3.4 µm (n= 30), hyaline, smooth, ellipsoidal, or clavate, aseptate, biguttulate. Beta conidia not observed. Conidial drops were yellow. The morphological characteristics of FJ1 and FJ21 were similar to those of Diaporthe spp.. DNA of two isolates was extracted, and the internal transcribed spacer region (ITS) and partial sequences of translation elongation factor 1-alpha (TEF1-α), calmodulin (CAL), ß-tubulin (TUB), and histone H3 (HIS) genes were amplified with primers ITS1/ITS4, EF1-728F/EF1-986R, CAL228F/CAL737R, ßt2a/ßt2b, and CYLH3F/H3-1b, respectively. The sequences were deposited in GenBank (accession nos. MW585608 and MW768905 to MW768908 for FJ1; MT755625 and MT776728 to MT776731 for FJ21). The BLASTn results showed that the ITS, TEF1-α, TUB, HIS, and CAL sequences of FJ1 were 100, 99, 98, 98, and 99% identical to those of D. eres (NR144923, KJ210550, KJ420799, KJ420850, and KJ434999, respectively). For FJ21, BLASTing with the same loci showed 100, 100, 100, 99, and 100% similarity with those of D. unshiuensis (MH121530, MH121572, MH121607 MH121488, and MH121448, respectively). Phylogenetic analyses with the concatenated sequences placed FJ1 and FJ21 in the clades of D. eres and D. unshiuensis, respectively. Pathogenicity tests were performed by wounding leaves of 2-year-old soapberry seedlings with a sterile needle. The leaves were inoculated with D. eres and D. unshiuensis isolates, respectively, with 10 µl of conidial suspensions (106 conidia/ml). Three plants were used for each treatment, and the leaves of each plant were inoculated. The control was treated with 10 µl of sterile water. The plants were kept in a greenhouse (RH > 80%, 25 ± 2°C). In 5 days, all inoculated leaves showed lesions similar to the field symptoms. Controls were asymptomatic. Diaporthe eres and D. unshiuensis were reisolated from the diseased leaves. No fungus was isolated from the control. Previously, D. biconispora and D. sapindicola were reported as the causal agents of soapberry, but this is the first report of D. eres and D. unshiuensis causing leaf spots on S. mukorossi in China. These data will help develop effective strategies for managing this disease.

Noncanonical autophagy at ER exit sites regulates procollagen turnover.

Type I collagen is the main component of bone matrix and other connective tissues. Rerouting of its procollagen precursor to a degradative pathway is crucial for osteoblast survival in pathologies involving excessive intracellular buildup of procollagen that is improperly folded and/or trafficked. What cellular mechanisms underlie this rerouting remains unclear. To study these mechanisms, we employed live-cell imaging and correlative light and electron microscopy (CLEM) to examine procollagen trafficking both in wild-type mouse osteoblasts and osteoblasts expressing a bone pathology-causing mutant procollagen. We found that although most procollagen molecules successfully trafficked through the secretory pathway in these cells, a subpopulation did not. The latter molecules appeared in numerous dispersed puncta colocalizing with COPII subunits, autophagy markers and ubiquitin machinery, with more puncta seen in mutant procollagen-expressing cells. Blocking endoplasmic reticulum exit site (ERES) formation suppressed the number of these puncta, suggesting they formed after procollagen entry into ERESs. The punctate structures containing procollagen, COPII, and autophagic markers did not move toward the Golgi but instead were relatively immobile. They appeared to be quickly engulfed by nearby lysosomes through a bafilomycin-insensitive pathway. CLEM and fluorescence recovery after photobleaching experiments suggested engulfment occurred through a noncanonical form of autophagy resembling microautophagy of ERESs. Overall, our findings reveal that a subset of procollagen molecules is directed toward lysosomal degradation through an autophagic pathway originating at ERESs, providing a mechanism to remove excess procollagen from cells.

First Report of Postharvest Fruit Rot Disease of Hardy Kiwifruit Caused by Diaporthe eres in China.

Hardy kiwifruit (Actinidia arguta), as an economically important fruit crop growing in Northeast China with thin, hairless and smooth skin, is susceptible to postharvest decay. In September 2018, infected cultivar Kwilv fruits were obtained from a commercial farm in Liaoning province, northeastern China. The occurring incidence of the rot disease varied from 20% to 90% according to the fruit number in each box during a 7-day-long storage at room temperature, and the initial symptom included a small, soft, chlorosis to light brown lesion and later watery brown lesions. Pure cultures of the same characteristics were obtained from the isolated strains in four rotten fruits on PDA medium. The isolates grew into transparent radial mycelium on PDA in the first two days followed by abundant white, fluffy aerial mycelium. After 14 days, colonies formed white to light brown aerial mycelial mats with gray concentric rings, and they produced gray and embedded pycnidia. Alpha conidia of 4.4 to 8.8 µm × 1.4 to 3.3 µm (n = 50) were abundant in culture, hyaline, aseptate, ellipsoidal to fusiform, while Beta conidia at 20.5 to 28.6 µm × 1.0 to 1.4 µm (n = 50) were hyaline, long, slender, curved to hamate. These morphological characteristics were similar to Diaporthe species (anamorph: Phomopsis spp.) (Udayanga et al. 2014). For identification, DNA was extracted from three single isolates respectively , and the internal transcribed spacer (ITS) region, ß-tubulin (BT), and histone (HIS) H3 gene were amplified by using primers ITS1/ITS4 (White et al. 1990), T1/T22 (O'Donnell et al. 1997) and HIS1F/HISR (Gao et al. 2017), respectively. The three isolates produced identical sequences across all three gene regions, which were submitted to NCBI (Genbank accession numbers MT561361, MT561360 and MT855966). Nucleotide BLAST analysis revealed that the ITS sequence shared 99% homology with those of ex-type Diaporthe eres in NCBI GenBank (MG281047.1 and KJ210529.1), so did the BT sequence that had 98% identity to D. eres (MG281256.1 and KJ420799.1) and the HIS 99% identity to D. eres (MG28431.1 and MG281395.1) (Hosseini et al. 2020, Udayanga et al. 2014). Pathogenicity was tested by wound inoculation on the cv. Kwilv fruits. Five mature and healthy fruits were surface-sterilized with 1% NaClO solution, rinsed in sterile distilled water and dried. Every fruit was wounded by penetrate the peel 1-2 mm with a sterile needle, and inoculated with mycelium plugs (5 mm in diameter) of the isolate on PDA, with five inoculated with sterile PDA plugs as controls. Treated fruits were kept in sterilized transparent plastic cans separately under high humidity (RH 90 to 100%) at 28°C. After five days, the same rot symptoms were observed on all fruits inoculated with mycelium while the control remained symptomless. The fungi was re-isolated from the lesions of inoculated fruits and identified as D. eres by sequencing, thus fulfilling Koch's postulates. The pathogenicity experiment was re-performed using D. eres conidial suspension (107 conidia/ml) in sterile distilled water in October 2019 and the same results were obtained. D. eres was recently reported to cause European pear rot in Italy (Bertetti et al. 2018). To our knowledge, this is the first report of D. eres causing a postharvest rot in hardy kiwifruit in China, leading to severe disease and thus huge economic losses in Northeast China. Accordingly, effective measures should be taken to prevent its spreading to other production regions in China.