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Appressorium

February 15, 2024

An appressorium is a specialized cell typical of many fungal plant pathogens that is used to infect host plants. It is a flattened, hyphal "pressing" organ, from which a minute infection peg grows and enters the host, using turgor pressure capable of punching through even Mylar.[1][2]

Germinating conidiospores of Hyaloperonospora parasitica. Observe the appressorium on top right.

Following spore attachment and germination on the host surface, the emerging germ tube perceives physical cues such as surface hardness and hydrophobicity, as well as chemical signals including wax monomers that trigger appressorium formation. Appressorium formation begins when the tip of the germ tube ceases polar growth, hooks, and begins to swell. The contents of the spore are then mobilized into the developing appressorium, a septum develops at the neck of the appressorium, and the germ tube and spore collapse and die. As the appressorium matures, it becomes firmly attached to the plant surface and a dense layer of melanin is laid down in the appressorium wall, except across a pore at the plant interface. Turgor pressure increases inside the appressorium and a penetration hypha emerges at the pore, which is driven through the plant cuticle into the underlying epidermal cells. The osmotic pressure exerted by the appressorium can reach up to 8 MPa, which allows it to puncture the plant cuticle.[3] This pressure is achievable due to a melanin-pigmented cell wall which is impermeable to compounds larger than water molecules, so the highly-concentrated ions cannot escape from it.[4]

Formation edit

The attachment of a fungal spore on the surface of the host plant is the first critical step of infection. Once the spore is hydrated, an adhesive mucilage is released from its tip.[5] During germination, mucilaginous substances continue to be extruded at the tips of the germ tube, which are essential for germ tube attachment and appressorium formation.[6] Spore adhesion and appressorium formation is inhibited by hydrolytic enzymes such as α-mannosidase, α-glucosidase, and protease, suggesting that the adhesive materials are composed of glycoproteins.[6][7] Germination is also inhibited at high spore concentrations, which might be due to a lipophilic self inhibitor. Self inhibition can be overcome by hydrophobic wax from rice leaf.[8]

 
Uromyces appendiculatus, germ tube and appressorium

In response to surface signals, the germ tube tip undergoes a cell differentiation process to form a specialized infection structure, the appressorium. Frank B. (1883), in 'Ueber einige neue und weniger bekannte Pflanzenkrankheiten', coined the name "appressorium" for the adhesion body formed by the bean pathogen Gloeosporium lindemuthianum on the host surface.[9]

Appressorium development involves a number of steps: nuclear division, first septum formation, germling emergence, tip swelling and second septum formation. Mitosis first occurs soon after surface attachment, and a nucleus from the second round of mitosis during tip swelling migrates into the hooked cell before septum formation. A mature appressorium normally contains a single nucleus.[2][10] The outside plasma membrane of the mature appressorium is covered by a melanin layer except at the region in contact with the substratum, where the penetration peg, a specialized hypha that penetrates the tissue surface, develops.[2][11] Cellular glycerol concentration sharply increases during spore germination, but it rapidly decreases at the point of appressorium initiation, and then gradually increases again during appressorium maturation. This glycerol accumulation generates high turgor pressure in the appressorium, and melanin is necessary for maintaining the glycerol gradient across the appressorium cell wall.[12]

Initiation edit

Appressoria are induced in response to physical cues including surface hardness and hydrophobicity, as well as chemical signals of aldehydes[13] exogenous cAMP, ethylene, the host's ripening hormone and the plant cutin monomer hexadecanoic acid.[14][15] Long chain fatty acids and the tripeptide sequence Arg-Gly-Asp inhibit appressorium induction.[16][17]

Rust fungi only form appressoria at stomata, since they can only infect plants through these pores. Other fungi tend to form appressoria over anticlinal cell walls, and some form them at any location.[18][19]

References edit

  1. ^ Howard RJ, Ferrari MA, Roach DH, Money NP (1991). "Penetration of hard substrates by a fungus employing enormous turgor pressures". Proceedings of the National Academy of Sciences. 88 (24): 11281–84. Bibcode:1991PNAS...8811281H. doi:10.1073/pnas.88.24.11281. PMC 53118. PMID 1837147.
  2. ^ a b c Howard RJ, Valent B (1996). "Breaking and entering: host penetration by the fungal rice blast pathogen Magnaporthe grisea". Annual Review of Microbiology. 50: 491–512. doi:10.1146/annurev.micro.50.1.491. PMID 8905089.
  3. ^ Fitopatologia. T. 1, Podstawy fitopatologii. Selim Kryczyński, Zbigniew Weber, Barbara Gołębniak. Poznań: Powszechne Wydawnictwo Rolnicze i Leśne. 2010. ISBN 978-83-09-01063-0. OCLC 802060485.{{cite book}}: CS1 maint: others (link)
  4. ^ Howard, Richard J.; Ferrari, Margaret A. (1989-12-01). "Role of melanin in appressorium function". Experimental Mycology. 13 (4): 403–418. doi:10.1016/0147-5975(89)90036-4. ISSN 0147-5975.
  5. ^ Braun EJ, Howard RJ (1994). "Adhesion of fungal spores and germlings to host-plant surfaces". Protoplasma. 181 (1–4): 202–12. doi:10.1007/BF01666396. S2CID 35667834.
  6. ^ a b Xiao JZ, Ohsima A, Kamakura T, Ishiyama T, Yamaguchi I (1994). "Extracellular glycoprotein(s) associated with cellular differentiation in Magnaporthe grisea" (PDF). Molecular Plant-Microbe Interactions. 7 (5): 639–44. doi:10.1094/MPMI-7-0639.
  7. ^ Ohtake M, Yamamoto H, Uchiyama T (1999). "Influences of metabolic inhibitors and hydrolytic enzymes on the adhesion of appressoria of Pyricularia oryzae to wax-coated cover-glasses" (PDF). Bioscience, Biotechnology, and Biochemistry. 63 (6): 978–82. doi:10.1271/bbb.63.978. PMID 27389332.
  8. ^ Hegde Y; Kolattukudy PE (1997). "Cuticular waxes relieve self-inhibition of germination and appressorium formation by the conidia of Magnaporthe grisea". Physiological and Molecular Plant Pathology. 51 (2): 75–84. doi:10.1006/pmpp.1997.0105.
  9. ^ Deising HB, Werner S, Wernitz M (2000). "The role of fungal appressoria in plant infection". Microbes and Infection / Institut Pasteur. 2 (13): 1631–41. doi:10.1016/S1286-4579(00)01319-8. PMID 11113382.
  10. ^ Shaw BD, Kuo KC, Hoch HC (1998). "Germination and appressorium development of Phyllosticta ampelicida pycnidiospores". Mycologia. 90 (2): 258–68. doi:10.2307/3761301. JSTOR 3761301.
  11. ^ Bourett TM, Howard RJ (1990). "In vitro development of penetration structures in the rice blast fungus Magnaporthe grisea". Canadian Journal of Botany. 68 (2): 329–42. doi:10.1139/b90-044.
  12. ^ deJong JC, McCormack BJ, Smirnoff N, Talbot NJ (1997). "Glycerol generates turgor in rice blast". Nature. 389 (6648): 244–5. Bibcode:1997Natur.389..244D. doi:10.1038/38418. S2CID 205026525.
  13. ^ Zhu, M., et al. (2017). Very-long-chain aldehydes induce appressorium formation in ascospores of the wheat powdery mildew fungus Blumeria graminis. Fungal biology 121(8): 716-728. https://doi.org/10.1016/j.funbio.2017.05.003
  14. ^ Flaishman MA, Kolattukudy PE (1994). "Timing of fungal invasion using host's ripening hormone as a signal". Proceedings of the National Academy of Sciences of the United States of America. 91 (14): 6579–83. Bibcode:1994PNAS...91.6579F. doi:10.1073/pnas.91.14.6579. PMC 44246. PMID 11607484.
  15. ^ Gilbert RD, Johnson AM, Dean RA (1996). "Chemical signals responsible for appressorium formation in the rice blast fungus Magnaporthe grisea". Physiological and Molecular Plant Pathology. 48 (5): 335–46. doi:10.1006/pmpp.1996.0027.
  16. ^ Lee YH, Dean RA (1993). "cAMP regulates infection structure formation in the plant-pathogenic fungus Magnaporthe grisea" (PDF). Plant Cell. 5 (6): 693–700. doi:10.2307/3869811. JSTOR 3869811. PMC 160306. PMID 12271080.
  17. ^ Correa A, Staples RC, Hoch HC (1996). "Inhibition of thigmostimulated cell differentiation with RGD-peptides in Uromyces germlings". Protoplasma. 194 (1–2): 91–102. doi:10.1007/BF01273171. S2CID 8417737.
  18. ^ Hoch, H. C.; Staples, R. C. (1987). "Structural and Chemical Changes Among the Rust Fungi During Appressorium Development". Annual Review of Phytopathology. 25: 231–247. doi:10.1146/annurev.py.25.090187.001311.
  19. ^ Dean, R. A. (1997). "Signal Pathways and Appressorium Morphogenesis". Annual Review of Phytopathology. 35: 211–234. doi:10.1146/annurev.phyto.35.1.211. PMID 15012522.

February 15, 2024
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An appressorium is a specialized cell typical of many fungal plant pathogens that is used to infect host plants It is a flattened hyphal pressing organ from which a minute infection peg grows and enters the host using turgor pressure capable of punching through even Mylar 1 2 Germinating conidiospores of Hyaloperonospora parasitica Observe the appressorium on top right Following spore attachment and germination on the host surface the emerging germ tube perceives physical cues such as surface hardness and hydrophobicity as well as chemical signals including wax monomers that trigger appressorium formation Appressorium formation begins when the tip of the germ tube ceases polar growth hooks and begins to swell The contents of the spore are then mobilized into the developing appressorium a septum develops at the neck of the appressorium and the germ tube and spore collapse and die As the appressorium matures it becomes firmly attached to the plant surface and a dense layer of melanin is laid down in the appressorium wall except across a pore at the plant interface Turgor pressure increases inside the appressorium and a penetration hypha emerges at the pore which is driven through the plant cuticle into the underlying epidermal cells The osmotic pressure exerted by the appressorium can reach up to 8 MPa which allows it to puncture the plant cuticle 3 This pressure is achievable due to a melanin pigmented cell wall which is impermeable to compounds larger than water molecules so the highly concentrated ions cannot escape from it 4 Formation editThe attachment of a fungal spore on the surface of the host plant is the first critical step of infection Once the spore is hydrated an adhesive mucilage is released from its tip 5 During germination mucilaginous substances continue to be extruded at the tips of the germ tube which are essential for germ tube attachment and appressorium formation 6 Spore adhesion and appressorium formation is inhibited by hydrolytic enzymes such as a mannosidase a glucosidase and protease suggesting that the adhesive materials are composed of glycoproteins 6 7 Germination is also inhibited at high spore concentrations which might be due to a lipophilic self inhibitor Self inhibition can be overcome by hydrophobic wax from rice leaf 8 nbsp Uromyces appendiculatus germ tube and appressoriumIn response to surface signals the germ tube tip undergoes a cell differentiation process to form a specialized infection structure the appressorium Frank B 1883 in Ueber einige neue und weniger bekannte Pflanzenkrankheiten coined the name appressorium for the adhesion body formed by the bean pathogen Gloeosporium lindemuthianum on the host surface 9 Appressorium development involves a number of steps nuclear division first septum formation germling emergence tip swelling and second septum formation Mitosis first occurs soon after surface attachment and a nucleus from the second round of mitosis during tip swelling migrates into the hooked cell before septum formation A mature appressorium normally contains a single nucleus 2 10 The outside plasma membrane of the mature appressorium is covered by a melanin layer except at the region in contact with the substratum where the penetration peg a specialized hypha that penetrates the tissue surface develops 2 11 Cellular glycerol concentration sharply increases during spore germination but it rapidly decreases at the point of appressorium initiation and then gradually increases again during appressorium maturation This glycerol accumulation generates high turgor pressure in the appressorium and melanin is necessary for maintaining the glycerol gradient across the appressorium cell wall 12 Initiation editAppressoria are induced in response to physical cues including surface hardness and hydrophobicity as well as chemical signals of aldehydes 13 exogenous cAMP ethylene the host s ripening hormone and the plant cutin monomer hexadecanoic acid 14 15 Long chain fatty acids and the tripeptide sequence Arg Gly Asp inhibit appressorium induction 16 17 Rust fungi only form appressoria at stomata since they can only infect plants through these pores Other fungi tend to form appressoria over anticlinal cell walls and some form them at any location 18 19 References edit Howard RJ Ferrari MA Roach DH Money NP 1991 Penetration of hard substrates by a fungus employing enormous turgor pressures Proceedings of the National Academy of Sciences 88 24 11281 84 Bibcode 1991PNAS 8811281H doi 10 1073 pnas 88 24 11281 PMC 53118 PMID 1837147 a b c Howard RJ Valent B 1996 Breaking and entering host penetration by the fungal rice blast pathogen Magnaporthe grisea Annual Review of Microbiology 50 491 512 doi 10 1146 annurev micro 50 1 491 PMID 8905089 Fitopatologia T 1 Podstawy fitopatologii Selim Kryczynski Zbigniew Weber Barbara Golebniak Poznan Powszechne Wydawnictwo Rolnicze i Lesne 2010 ISBN 978 83 09 01063 0 OCLC 802060485 a href Template Cite book html title Template Cite book cite book a CS1 maint others link Howard Richard J Ferrari Margaret A 1989 12 01 Role of melanin in appressorium function Experimental Mycology 13 4 403 418 doi 10 1016 0147 5975 89 90036 4 ISSN 0147 5975 Braun EJ Howard RJ 1994 Adhesion of fungal spores and germlings to host plant surfaces Protoplasma 181 1 4 202 12 doi 10 1007 BF01666396 S2CID 35667834 a b Xiao JZ Ohsima A Kamakura T Ishiyama T Yamaguchi I 1994 Extracellular glycoprotein s associated with cellular differentiation in Magnaporthe grisea PDF Molecular Plant Microbe Interactions 7 5 639 44 doi 10 1094 MPMI 7 0639 Ohtake M Yamamoto H Uchiyama T 1999 Influences of metabolic inhibitors and hydrolytic enzymes on the adhesion of appressoria of Pyricularia oryzae to wax coated cover glasses PDF Bioscience Biotechnology and Biochemistry 63 6 978 82 doi 10 1271 bbb 63 978 PMID 27389332 Hegde Y Kolattukudy PE 1997 Cuticular waxes relieve self inhibition of germination and appressorium formation by the conidia of Magnaporthe grisea Physiological and Molecular Plant Pathology 51 2 75 84 doi 10 1006 pmpp 1997 0105 Deising HB Werner S Wernitz M 2000 The role of fungal appressoria in plant infection Microbes and Infection Institut Pasteur 2 13 1631 41 doi 10 1016 S1286 4579 00 01319 8 PMID 11113382 Shaw BD Kuo KC Hoch HC 1998 Germination and appressorium development of Phyllosticta ampelicida pycnidiospores Mycologia 90 2 258 68 doi 10 2307 3761301 JSTOR 3761301 Bourett TM Howard RJ 1990 In vitro development of penetration structures in the rice blast fungus Magnaporthe grisea Canadian Journal of Botany 68 2 329 42 doi 10 1139 b90 044 deJong JC McCormack BJ Smirnoff N Talbot NJ 1997 Glycerol generates turgor in rice blast Nature 389 6648 244 5 Bibcode 1997Natur 389 244D doi 10 1038 38418 S2CID 205026525 Zhu M et al 2017 Very long chain aldehydes induce appressorium formation in ascospores of the wheat powdery mildew fungus Blumeria graminis Fungal biology 121 8 716 728 https doi org 10 1016 j funbio 2017 05 003 Flaishman MA Kolattukudy PE 1994 Timing of fungal invasion using host s ripening hormone as a signal Proceedings of the National Academy of Sciences of the United States of America 91 14 6579 83 Bibcode 1994PNAS 91 6579F doi 10 1073 pnas 91 14 6579 PMC 44246 PMID 11607484 Gilbert RD Johnson AM Dean RA 1996 Chemical signals responsible for appressorium formation in the rice blast fungus Magnaporthe grisea Physiological and Molecular Plant Pathology 48 5 335 46 doi 10 1006 pmpp 1996 0027 Lee YH Dean RA 1993 cAMP regulates infection structure formation in the plant pathogenic fungus Magnaporthe grisea PDF Plant Cell 5 6 693 700 doi 10 2307 3869811 JSTOR 3869811 PMC 160306 PMID 12271080 Correa A Staples RC Hoch HC 1996 Inhibition of thigmostimulated cell differentiation with RGD peptides in Uromyces germlings Protoplasma 194 1 2 91 102 doi 10 1007 BF01273171 S2CID 8417737 Hoch H C Staples R C 1987 Structural and Chemical Changes Among the Rust Fungi During Appressorium Development Annual Review of Phytopathology 25 231 247 doi 10 1146 annurev py 25 090187 001311 Dean R A 1997 Signal Pathways and Appressorium Morphogenesis Annual Review of Phytopathology 35 211 234 doi 10 1146 annurev phyto 35 1 211 PMID 15012522 Retrieved from https en wikipedia org w index php title Appressorium amp oldid 1184904073, wikipedia, wiki, book, books, library,

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