Litvinova V. V., Lavrentyeva K. V., Skliar T. V.

THE ROLE OF SOIL MICROFLORA IN PROCESSES OF MOBILIZATION OF PHOSPHORUS FROM ITS INSOLUBLE COMPOUNDS


About the author:

Litvinova V. V., Lavrentyeva K. V., Skliar T. V.

Heading:

LITERATURE REVIEWS

Type of article:

Scentific article

Annotation:

Excessive and unbalanced use of pesticides and mineral fertilizers in order to increase the productivity of agricultural plants adversely affects the acid-base properties, chemical composition and biological component of the soil. As a result, its phytosanitary condition deteriorates, fertility declines. Recently, the world has seen a transition to the practice of biologization of agriculture, which consists in replacing chemicals with ecologically safe biofertilizers based on soil microorganisms that not only promote the improvement of mineral nutrition of plants and increase their productivity, but also enhance its resistance to stress factors, inhibit the multiplication of phytopathogenic species, reduce the pesticide load on agrocenosis. In this regard, the development and introduction of such preparations in agriculture is especially relevant. Of considerable interest are biofertilizers based on phosphate-mobilizing soil microflora, capable of translating poorly soluble phosphorus compounds in the soil into a soluble form and thereby optimizing the phosphorous nutrition of plants. It is to this promising direction of biotechnology that this literature review is devoted. The paper contains data on the content and quantitative ratio of phosphate forms in the soils of Ukraine, the role of phosphorus and its compounds in the vital activity of the plant organism. It is shown that in black earth phosphorus is mainly in the form of sparingly soluble mineral salts, which contain a phosphate anion bound to the cations Ca2+ , Mg 2+ , Al 3+ , Fe 2+ , Mn 2+ . Most of the organic compounds of phosphorus are represented by humus, phosphatides, sugar phosphates, nucleic acids, phytin and phytates with a low rate of mineralization. It is known that the rhizosphere phosphate-mobilizing microflora plays the main role in the transformation of poorly soluble inorganic and organic phosphates. Its species composition is represented by bacteria (Bacillus sp., B. megaterium, B. mycoides, B. cereus, B. subtilis, Pseudomonas sp., P. putida, P. striata, P. fluorescens, Erwinia sp., Enterobacter sp., Micrococcus sp., etc.), fungi (Aspergillus awamori, A. niger, A. flavus, Morteirella sp., Micromonospora sp., Mucor. sp., Penicillium digitatum, P. lilacinium, P. balaji, etc.) actinomycetes (Actinomyces sp., Streptomyces sp.), cyanobacteria (Anabena sp., Nostoc sp., Scytonema sp.). Many research works indicate that the transformation of phosphorus-containing compounds by these microorganisms can occur in accordance with three basic mechanisms: acid dissolution of phosphates; formation of chelated complexes with metal cations in the composition of mineral phosphorus-containing compounds by organic acids; enzymatic cleavage of organic compounds of phosphorus. On the basis of the most active of the isolated strains of soil phosphate-mobilizing bacteria, a number of mono- and complex biofertilizers have been created (“Polymyxobacterin”, “Phosphoenterin”, “Albobacterin”, “BiocomplexBTU”, “Ecovital”, “Nitrozlak”, “Organic Balance”), the effectiveness of which has been confirmed experimentally in numerous laboratory and field studies.

Tags:

phosphorus, phosphate-mobilizing microflora, phosphate mobilization, biofertilizers

Bibliography:

  1. Vdovenko SA, Shhigol’ VІ. Urozhajnіst’ gіbridіv kapusti brjussel’s’koi zalezhno vіd zastosuvannja bіopreparatіv. Vіsnik Umans’kogo nacіonal’nogo unіversitetu sadіvnictva. 2015;2:20-3. [in Ukrainian].
  2. Voznjuk SV, Ljaska SІ. Efektivnіst’ sumіsnogo vikoristannja kompleksnogo mіkrobnogo preparatu Ekovіtal і reguljatorіv rostu roslin. Mіkrobіologіja v suchasnomu sіl’s’kogospodars’komu virobnictvі: materіali ІХ naukovoi konferencіi molodih vchenih; 2013 listop 26-27; Chernіgіv, Chernіgіv: Sіver-Druk; 2013, s. 55-7. [in Ukrainian].
  3. Voznjuk SV, Titova LV, Iutinskaja GA. Osobennosti formirovanija soevo-rizobial’nyh sistem pri primenenii fungicidov i kompleksnoj inokuljacii. Naukovі zapiski Ternopіl’s’kogo nacіonal’nogo pedagogіchnogo unіversitetu. Serіja: Bіologіja. 2014;3(60):61-4. [in Russiаn].
  4. V’juncov SM. Formuvannja produktivnostі l’onu-dovguncja zalezhno vіd zastosuvannja mіkrobnogo preparatu polіmіksobakterin. Vіsnik Zhitomirs’kogo nacіonal’nogo agroekologіchnogo unіversitetu. 2016;53(1):125-31. [in Ukrainian].
  5. German MM, Marenich MM. Efektivnіst’ peredposіvnoji obrobki nasіnnja fosfatmobіlіzujuchimi preparatami pshenicі m’jakoi ozimoi. Vіsnik Poltavs’koi derzhavnoi agrarnoi akademіi. 2013;2:19-21. [in Ukrainian].
  6. Gospodarenko GM, Prokopchuk ІV. Transformacіja kislotno-osnovnih vlastivostej gruntu za trivalogo zastosuvannja dobriv u pol’ovіj sіvozmіnі. Vіsnik Umans’kogo nacіonal’nogo unіversitetu sadіvnictva. 2014;1:8-12. [in Ukrainian].
  7. Grigor’еva OM, Grigor’eva TM, Lіman PB, Tokmakova LM. Vpliv mіkrobnih preparatіv na produktivnіst’ zernovih kul’tur u pіvnіchnomu stepu Ukraini. Sіl’s’kogospodars’ka mіkrobіologіja. 2012;15-16:49-57. [in Ukrainian].
  8. Grigor’еva OM, Grigor’eva MІ. Mіkrobnі preparati u tehnologіi viroshhuvannja kukurudzi na zerno v pіvnіchnomu stepu Ukraini. Zbіrnik naukovih prac’ Umans’kogo nacіonal’nogo unіversitetu sadіvnictva. 2011;76:8-23. [in Ukrainian].
  9. Grigor’еva TM. Efektivnіst’ zastosuvannja mіneral’nih dobriv u kombіnacіу z mіkrobnimi preparatami pri viroshhuvannі jachmenju jarogo. Sіl’s’kogospodars’ka mіkrobіologіja. 2014;19:21-6. [in Ukrainian].
  10. Derzhavnij reеstr pesticidіv і agrohіmіkatіv, dozvolenih do vikoristannja v Ukrainі (rozpochato z 01.01.2008 r. zgіdno z vimogami postanovi Kabіnetu Mіnіstrіv Ukraini vіd 21.11.2007 № 1328) [Іnternet]. Kiiv: Mіnіsterstvo ekologіі ta prirodnih resursіv Ukraini; 2017 [onovleno 08 kvіtnja 2017; citovano 05 sіchnja 2018]. Dostupno: https://menr.gov.ua/content/derzhavniy-reestr-pesticidiv-i-agrohimikativ-dozvolenihdo-vikoristannya-v-ukraini-dopovnennya-z-01012017-zgidno-vimog-postanovi-kabinetu-ministriv-ukraini-vid-21112007-1328.html [in Ukrainian].
  11. Dubovik DJu, Olefіrenko BA. Efektivnіst’ zastosuvannja bіodobriv na posіvah pshenicі ozimoі. Mironіvs’kij vіsnik. 2016;2:214-48. [in Ukrainian].
  12. Іutins’ka GO. Mіkrobnі bіotehnologіi dlja realіzacіi novoi global’noi programi zabezpechennja stalogo rozvitku agrosferi Ukraini. Agroekologіchnij zhurnal. 2017;2:149-54. [in Ukrainian].
  13. Iutinskaja GA. Biologicheskie preparaty kompleksnogo dejstvija dlja povyshenija effektivnosti mikrobno-rastitel’nyh sistem. Materialy Shestoj Mezhdunarodnoj konferencii Radostim. Biologicheskie preparaty i reguljatory rosta rastenij v sel’skom hozjajstve [Internet]; 2010 nojabr 24-25; Krasnodar, Krasnodar: Kubanskij gosudarstvennyj agrarnyj universitet; 2010 [citirovano 2018 Janv 05]; s. 19-23. Dostupno: http://www.darostim-conference.info/2010/2010%20ru/Word%20Formulare/Radostim_2010_Talk_Catalogue.pdf [in Russiаn].
  14. Iutinskaja GA, Ponomarenko SP, redaktory. Bioreguljacija mikrobno-rastitel’nyh sistem: Monografija. Kiev: «Nіchlava»; 2010. 472 s. [in Russiаn].
  15. Kovalenko OA, Kljuchnik MA, Chebanenko KV. Zastosuvannja bіopreparatіv dlja obrobki nasіnnevogo materіalu pshenicі ozimoi. Naukovі pracі. Ekologіja. 2015;256(244):74-7. [in Ukrainian].
  16. Kovpak PV, Tokmakova LM, Larchenko ІV, Trepach AO. Chisel’nіst’ fosfatmobіlіzuval’nih bakterіj u korenevіj zonі roslin pshenicі za dіi polіmіksobakterinu ta mіneral’nih dobriv. Sіl’s’kogospodars’ka mіkrobіologіja. 2013;17:101-10. [in Ukrainian].
  17. Kolodjazhnij OJu. Formuvannja mіkrobnogo kompleksu chornozemu tipovogo v agrocenozі pshenicі ozimoу za rіznih sistem zemlerobstva [disertacіja]. Kiiv: Nacіonal’nij unіversitet bіoresursіv ta prirodokoristuvannja Ukraini; 2015. 230 s. [in Ukrainian].
  18. Koshevs’kij II, Ljaska SІ. Vpliv іnokuljacіi soi bіologіchnimi preparatami na rozvitok gribnih hvorob. Naukovij vіsnik Nacіonal’nogo unіversitetu bіoresursіv і prirodokoristuvannja Ukraini. Serіja: Bіologіja, bіotehnologіja, ekologіja. 2014;204:127-31. [in Ukrainian].
  19. Koshkin EI. Patofiziologija sel’skohozjajstvennyh kul’tur: uchebnoe posobie. Moskva: RG-Press; 2016. 303 s. [in Russiаn].
  20. Kramar’ov SM, Kramar’ov OS, Pisarenko OV, Hristenko AO, Tokmakova LM, Zhuchenko SІ, ta іn. Zmіna vmіstu ruhomogo fosforu v genetichnih gorizontah chornozemu zvichajnogo na rіllі vіdnosno cіlini v umovah pіvnіchnogo stepu Ukraуni. Vіsnik Poltavs’koi derzhavnoi agrarnoi akademіi. 2014;7-22. [in Ukrainian].
  21. Kurdish ІK. Іntrodukcіja mіkroorganіzmіv u agrosistemi. Kiiv: «Naukova dumka»; 2010. 255 s.[in Ukrainian].
  22. Kurdish ІK. Perspektiva zastosuvannja mіkrobіv-antagonіstіv u zahistі agroekosistem vіd fіtopatogenіv. Sіl’s’kogospodars’ka mіkrobіologіja. 2011;13:23-41. [in Ukrainian].
  23. Medvedev SS. Fiziologija rastenij: uchebnik. Sankt-Peterburg: BHV-Peterburg; 2012. 512 s. [in Russiаn].
  24. Mel’nichuk TM, Chajkovs’ka LO, Kameneva ІO, Jakubovs’ka AІ, Lolojko OA. Fіzіologo-bіohіmіchnі aspekti vzaemodіi bіoagentіv mіkrobnih preparatіv ta roslin. Naukovі zapiski Ternopіl’s’kogo nacіonal’nogo pedagogіchnogo unіversitetu. Serіja: Bіologіja. 2014;3(60):134-8. [in Ukrainian].
  25. Najd’onova OE, Shedej LO, Sjabruk OP, Akіmova RV, Gvozdik VB. Zastosuvannja mіkrobnogo preparatu polіmіksobakterinu za viroshhuvannja sonjashnika v organіchnomu zemlerobstvі. Agrohіmіja і gruntoznavstvo. 2015;83:31-5. [in Ukrainian].
  26. Ostapchuk MO, Polіshhuk ІS, Mazur VA. Mіkrobіologіchnі preparati – skladova organіchnogo zemlerobstva. Zbіrnik naukovih prac’ Vіnnic’kogo nacіonal’nogo agrarnogo unіversitetu. 2011;7(47):11-6. [in Ukrainian].
  27. Perelіk pesticidіv і agrohіmіkatіv, dozvolenih do vikoristannja v Ukrainі [Іnternet]. Dostupno: http://agroscience.com.ua/perelik-pest/nitrozlak [in Ukrainian].
  28. Plіsko ІV, Dac’ko LV, Dem’janjuk OS. Vartіst’ osnovnih pozhivnih rechovin u gruntah Ukraini. Agroekologіchnij zhurnal. 2013;1:55-60. [in Ukrainian].
  29. Povh OV. Іntegrovane zastosuvannja organіchnih dobriv ta mіkrobіologіchnih preparatіv v suchasnih agrotehnologіjah. Vіsnik Centru naukovogo zabezpechennja agropromislovogo virobnictva Harkіvs’koу oblastі. 2014;16:287-95. [in Ukrainian].
  30. Rechkin AI, Ladygina GN. Geohimicheskaja rol’ mikroorganizmov: elektronnoe uchebnoe posobie. Nizhnij Novgorod: NGU; 2010. 72 s. [in Russiаn].
  31. Safronova GV, Aleshhenkova ZM, Mel’nikova NV, Vasina EV. Transformacija vodonerastvorimyh pochvennyh fosfatov mikroorganizmami. Sbornik nauchnyh trudov. Mikrobnye biotehnologii: fundamental’nye i prikladnye aspekty. Minsk: Belarusskaja navuka. 2011;3:192-210. [in Russiаn].
  32. Skidan OV, redaktor. Efektivnіst’ zahodіv organіchnogo viroshhuvannja cibulі porej. Zbіrnik materіalіv dopovіdej uchasnikіv IV Mіzhnarodnoi naukovo-praktichnoi konferencіi. Organіchne virobnictvo і prodovol’cha bezpeka; 2016 Trav 12-13; Zhitomir. Zhitomir: FOP OO. Jevenok; 2016. s. 118-21. [in Ukrainian].
  33. Stahіv MP. Fosforne zhivlennja roslin ta metodichnі aspekti viznachennja ruhomih spoluk fosforu v gruntі. Gruntoznavstvo. 2010;11(3-4):88-95. [in Ukrainian].
  34. Tehnologіi majbutn’ogo – mіkrobnі preparati. Katalog produkcіi kompanіi «BTU-Centr» [Іnternet]. Ladizhin: BTU-Centr «Bіotehnologіja Ukraini»; 2017 [citovano 2018 Sіchn 05]. Dostupno: http://btu-center.com/upload/images/catalog_2017/%D0%91%D0%A2%D0%A3-mail.pdf[in Ukrainian].
  35. Atekan, Nuraini Y, Handayanto E, Syekhfani. The potential of phosphate solubilizing bacteria isolated from sugarcane wastes for solubilizing phosphate. Journal of degraded and mining lands management. 2014;1(4):175-82.
  36. Behera BC, Singdevsachan SK, Mishra RR, Dutta SK, Thatoi HN. Diversity, mechanism and biotechnology of phosphate solubilizing microorganism in mangrove – a review. Biocatalysis and Agricultural Biotechnology. 2014;3(2):97-100.
  37. Habte M, Osorio NW. Effect of nitrogen form on the effectiveness of a phosphate-solubilizing fungus to dissolve rock phosphate. Biofertilizers & Biopesticides [Internet].2012 Oct 18 [cited 2018 Jan 05];3(127):1-4. Available from: https://www.omicsonline.org/effect-of-nitrogen-form-on-the-effectiveness-of-a-phosphate-solubilizing-fungus-to-dissolve-rock-phosphate-2155-6202.10000127.php?aid=9635 DOI:10.4172/2155-6202.10000127
  38. Hajjam Y, Cherkaoui S. The influence of phosphate solubilizing microorganisms on symbiotic nitrogen fixation: Perspectives for sustainable agriculture. Journal of Materials and Environmental Sciences. 2017;8(3):801-8.
  39. Halvorson HO, Keynan A, Kornberg HL. Utilization of calcium phosphates for microbial growth at alkaline pH. Soil Biology and Biochemistry. 1990;22(7):887-90.
  40. Krishnaraj PU, Danale S. Mineral Phosphate Solubilization: Concepts and Prospects in Sustainable Agriculture. Proceedings of the Indian National Science Academy. 2014;80(2):389-405.
  41. Mennan C. Bacterial acid phosphatase and its application to waste remediation and metal recovery [thesis for the degree of doctor of philosophy]. Birmingham; The University of Birmingham; 2010. 244 p.
  42. Panhvar QA, Jusop S, Naher UA, Othman R, Razi MI. Application of potential phosphate-solubilizing bacteria and organic acids on phosphate solubilization from phosphate rock in aerobic rice. The Scientific World Journal [Internet]. 2013 Aug 22 [cited 2018 Jan 05]; Article ID 272409:1-10. Available from: https://www.hindawi.com/journals/tswj/2013/272409
  43. Sarikhani MR. Increasing potassium (K) release from K-containing minerals in the presence of insoluble phosphate by bacteria. Biological Journal of Microorganism. 2016;4(16):87-96.
  44. Sharma SB, Sayyed RZ, Trivedi MH, Gobi TA. Phosphate solubilizing microbes: sustainable approach for managing phosphorus deficiency in agricultural soils. Springer Plus [Internet]. 2013 Oct 31 [cited 2018 Jan 05];2:587:1-10.Available from: https://springerplus.springeropen.com/articles/10.1186/2193-1801-2-587
  45. Whitelaw MA. Growth promotion of plants inoculated with phosphate-solubilizing fungi. Advances in Agronomy. 2000;69:100-51.
  46. Xu RK, Zhu YG, Chittleborough D. Phosphorus release from phosphate rock and an iron phosphate by low-molecular-weight organic acids. Journal of Environmental Sciences. 2004;16(1):5-8.

Publication of the article:

«Bulletin of problems biology and medicine» Issue 1 Part 1 (142), 2018 year, 40-45 pages, index UDK 631. 461 (477.63)

DOI: