Coniella Explained
Coniella is a fungus genus in the family Schizoparmeaceae (or Schizoparmaceae), which contains 65 species recorded in the database Mycobank.[1] [2] This genus Coniella are reported as a typical plant pathogenic fungi for grape,[3] eucalyptus [4] and several plant. It mainly found in Europe, Asian, also South Africa. less report in American, only one paper published new spaces founded.
The first fungus belonging to Coniella genus was Coniella pulchella, established by Von Hoehnel in 1918. (Von H.hnel 1918)[5] Alvarez, regarded genera Pilidiella and Schizoparme together with Coniella as synonyms. (Alvarez, Groenewald et al. 2016) [6] As typical plant pathogenic fungi and due to globalization, Coniella occur worldwide as plant pathogens. Coniella vitis and Coniella diplodiella are two common pathogens that cause white rot disease in grapevines.[7] Coniella granati induces crown rot and fruit rot in pomegranates in Central Asia.[8] In northern Australia, several species of Coniella have been reported to cause foliage blight on eucalyptus trees.[9] Several Coniella fungi from South Africa are harmful for grapevine cultivation.[10] In 2015, Coniella fragariae was reported as the causal agent for strawberry crown rot in Latvia.[11] Fewer reports about Coniella come from north and south America, but Coniella lustricola was isolated as a new species from submerged detritus in Black Moshannon State Park in Pennsylvania, USA.[12] Considerable research on this genus of fungi has been published in the field of agriculture and biology but there are far few reports about the secondary metabolites of Coniella. In the chemical constitution study, two paper reported azaphilone are the main metabolites.[13] [14]
External links
References
- Raudabaugh. Daniel B.. Iturriaga. Teresa. Carver. Akiko. Mondo. Stephen. Pangilinan. Jasmyn. Lipzen. Anna. He. Guifen. Amirebrahimi. Mojgan. Grigoriev. Igor V.. 2018-01-01. Coniella lustricola, a new species from submerged detritus. Mycological Progress. en. 17. 1. 191–203. 10.1007/s11557-017-1337-6. 245669. 1861-8952.
- Alvarez. L. V.. Groenewald. J. Z.. Crous. P. W.. 2016-09-01. Revising the Schizoparmaceae: Coniella and its synonyms Pilidiella and Schizoparme. Studies in Mycology. 85. 1–34. 10.1016/j.simyco.2016.09.001. 27766001. 5066162. 0166-0616.
- Chethana. K. W. T.. Zhou. Y.. Zhang. W.. Liu. M.. Xing. Q. K.. Li. X. H.. Yan. J. Y.. Chethana. K. W. T.. Hyde. K. D.. 2017-07-28. Coniella vitis sp. nov. Is the Common Pathogen of White Rot in Chinese Vineyards. Plant Disease. 101. 12. 2123–2136. 10.1094/PDIS-12-16-1741-RE. 30677388. 0191-2917. free.
- Rhodes. David. Stephens. Michael. 2014-11-26. Planted forest development in Australia and New Zealand: comparative trends and future opportunities. New Zealand Journal of Forestry Science. en. 44. 1. S10. 10.1186/1179-5395-44-S1-S10. 1179-5395. free.
- April 1920. Über die minimale Belichtungszeit, welche die Keimung der Samen von Lythrum Salicaria auslöst. Die Naturwissenschaften. 8. 16. 309. 10.1007/bf02448696. 1920NW......8Q.309.. 41169014. 0028-1042.
- Alvarez. L.V.. Groenewald. J.Z.. Crous. P.W.. September 2016. Revising the Schizoparmaceae: Coniella and its synonyms Pilidiella and Schizoparme. Studies in Mycology. 85. 1–34. 10.1016/j.simyco.2016.09.001. 27766001. 5066162. 0166-0616.
- Chethana. K. W. T.. Zhou. Y.. Zhang. W.. Liu. M.. Xing. Q. K.. Li. X. H.. Yan. J. Y.. Chethana. K. W. T.. Hyde. K. D.. December 2017. Coniella vitis sp. nov. Is the Common Pathogen of White Rot in Chinese Vineyards. Plant Disease. 101. 12. 2123–2136. 10.1094/pdis-12-16-1741-re. 30677388. 0191-2917. free.
- Çeliker. Naciye Mükerrem. Uysal. Ayşe. Çetinel. Barbaros. Poyraz. Dilek. 2012-10-16. Crown rot on pomegranate caused by Coniella granati in Turkey. Australasian Plant Disease Notes. 7. 1. 161–162. 10.1007/s13314-012-0074-6. 42485912. 1833-928X. free.
- Book: Janet, Griffiths, M.W. Wylie, F. Ross Lawson, Simon A. Pegg, Geoff S. McDonald. Known or potential threats from pests and diseases to prospective tree species for high value timber plantings in northern Australia. 2004. 1143219084.
- Van Niekerk. Jan M.. Groenewald. J. Z. ‘Ewald’. Verkley. Gerard J.M.. Fourie. Paul H.. Wingfield. Michael J.. Crous. Pedro W.. March 2004. Systematic reappraisal of Coniella and Pilidiella, with specific reference to species occurring on Eucalyptus and Vitis in South Africa. Mycological Research. 108. 3. 283–303. 10.1017/s0953756204009268. 15185979. 0953-7562.
- Grantina-Ievina. Lelde. 2015-12-01. Fungi Causing Storage Rot of Apple Fruit in Integrated Pest Management System and their Sensitivity to Fungicides. Rural Sustainability Research. 34. 329. 2–11. 10.1515/plua-2015-0007. 64274764. 2256-0939. free.
- Raudabaugh. Daniel B.. Iturriaga. Teresa. Carver. Akiko. Mondo. Stephen. Pangilinan. Jasmyn. Lipzen. Anna. He. Guifen. Amirebrahimi. Mojgan. Grigoriev. Igor V.. Miller. Andrew N.. 2017-09-13. Coniella lustricola, a new species from submerged detritus. Mycological Progress. 17. 1–2. 191–203. 10.1007/s11557-017-1337-6. 245669. 1617-416X.
- Yu. Haiqian. Sperlich. Julia. Höfert. Simon-Patrick. Janiak. Christoph. Teusch. Nicole. Stuhldreier. Fabian. Wesselborg. Sebastian. Wang. Chenyin. Kassack. Matthias U.. 2019-09-01. Azaphilone pigments and macrodiolides from the coprophilous fungus Coniella fragariae. Fitoterapia. 137. 104249. 10.1016/j.fitote.2019.104249. 31247219. 195765769. 0367-326X.
- Yu. Haiqian. Sperlich. Julia. Mándi. Attila. Kurtán. Tibor. Dai. Haofu. Teusch. Nicole. Guo. Zhi-Yong. Zou. Kun. Liu. Zhen. 2018-11-26. Azaphilone Derivatives from the Fungus Coniella fragariae Inhibit NF-κB Activation and Reduce Tumor Cell Migration. Journal of Natural Products. 81. 11. 2493–2500. 10.1021/acs.jnatprod.8b00540. 30354103. 53031014. 0163-3864.