[1] Zsogon A.,Peres LE.P.,Xiao Y.,Yan J.,Fernie A.R. .2022 .Enhancing crop diversity for food security in the face of climate uncertainty. The Plant Journal, 109 : 402-414.
[2] Paschalidou A.,Kyriazopoulos A.P.,Halbac-Cotoara-Zamfir R.,Siad S.M.,M. SuskaMalawska D.,Savic D.,J.R. de Pinho L.,Thalheimer D.S.,Williams N.,Hashimshony-Yafe N.,Ficko A. .2021 .Multidimensional food security nexus in drylands under the slow onset efects of climate change. Land, 1350(12) : .
[3] D.J.M. Hall S.L.,Davies R.W.,Bell T.J.,Edwards T.J. .2020 .Soil management systems to overcome multiple constraints for dryland crops on deep sands in a water limited environment on the south coast of western Australia. Agronomy, 10 : .
[4] Trigo A.,A. A.,Fragoso R. .2021 .Principles of sustainable agriculture: Defining standardized reference points. Sustainability, 13 : 4086.
[5] E.K.K. Jew S.,Whitfield A.J.,Dougill D.D.,Mkwambisi P.,Steward P. .2020 .Farming systems and conservation agriculture: Technology, structures and agency in Malawi. Land Use Policy, 95 : 104612.
[6] Schimel J.P. .2018 .Life in dry soils: Efects of drought on soil microbial communities and processes. Annual Review of Ecology, Evolution, and Systematics, 49(1) : 409-432.
[7] Sukorini H.,Putri E.R.T.,Ishartati E.,Sufianto S.,Setyobudi R.H.,Huu N.N.,S. Suwannarat. N.N. .2023 .Assessment on drought stress resistance, salinity endurance, and indole acetic acid production potential of dryland-isolated bacteria. Jordan Journal of Biological Sciences, 16(1) : 137-147.
[8] Borowik A.,Wyszkowska J. .2016 .Soil moisture as a factor afecting the microbiological and biochemical activity of soil. Plant, Soil and Environment, 62(6) : 250-255.
[9] Lüneberg K.,Schneider D.,Siebe C.,Daniel R. .2018 .Drylands soil bacterial community is afected by land use change and diferent irrigation practices in the Mezquital Valley, Mexico. Scientific Reports, 8 : 1413.
[10] Tian P.,Razavi B.S.,Zhang X.,Wang Q.,Blagodatskaya E. .2019 .Microbial growth and enzyme kinetics in rhizosphere hotspots are modulated by soil organics and nutrient availability. Soil Biology and Biochemistry, 141 : 107662.
[11] .2019 .Smart farming: Teknologi PGPR untuk keberlanjutan pertanian lahan kering. [Smart farming: PGPR technology for dry land farming sustainability]. Seminar Nasional Optimalisasi Sumberdaya Lokal di Era Revolusi Industri 4.0, : 615-622.
[12] Babalola O.O. .2018 .Microbial inoculants for improving crop quality and human health in Africa. Frontiers in Microbiology, 9 : 2213.
[13] O.B. Ojuederie O.S.,Olanrewaju O.O.,Babalola O.O. .2019 .Plant growth promoting rhizobacterial mitigation of drought stress in crop plants: Implications for sustainable agriculture. Agronomy, 712(11) : .
[14] Nguyen N.H.,Trotel-Aziz P.,Clément C.,Jeandet P.,Baillieul F.,Aziz A. .2022 .Camalexin accumulation as a component of plant immunity during interactions with pathogens and beneficial microbes. Journal Planta, 255(6) : 73-90.
[15] M. Saakre T.M.,Baburao A.P.,Salim R.M.,Ffancies V.P.,Achuthan S.R.,Sivarajan S.R. .2017 .Identification and characterization of genes responsible for drought tolerance in rice mediated by Pseudomonas fluorescens. Rice Science, 24(5) : 291-298.
[16] Helaly A.A.,Hassan S.M.,Craker L.E.,Mady E. .2020 .Efects of growth-promoting bacteria on growth, yield and nutritional value of collard plants. Annals of Agricultural Sciences, 65(1) : 77-82.
[17] Vejan P.,Abdullah R.,Khadiran T.,Ismail S.,Boyce A.N. .2016 .Role of plant growth promoting rhizobacteria in agricultural sustainability-A review. Molecules, 573(5) : .
[18] Iqrar Z.K.,Shinwari A.,El-Sayed G.S.,Ali G.S. .2019 .Bioactivity-driven high throughput screening of microbiomes of medicinal plants for discovering new biological control agents. BioRXiv, 1 : 26.
[19] Olanrewaju O.S.,Glick B.R.,Babalola O.O. .2017 .Mechanisms of action of plant growth promoting bacteria. World Journal of Microbiology and Biotechnology, 197(11) : .
[20] Schwinghamer T.,Fan D.,Smith D.L.,Gravel and V. .2019 .Bacillus sp. biofilms and planktonic cells. Applied Soil Ecology, 138 : 61-68.
[21] Gouda S.,Kerry R.G.,G. Das S.,Paramithiotis H.S.,Shin J.K.,Patra J.K. .2018 .Revitalization of plant growth promoting rhizobacteria for sustainable development in agriculture. Microbiological Research, 206(5) : 131-140.
[22] Shinwari Z.K.,Tanveer F.,and I. Iqrar. F.,Kumar Opportunities. V.,Prasad R.,Kumar M.,Choudhary D. .2019 .Microbiome in Plant Health and Disease: Challenges and. , : 231-250.
[23] M.C. Enebe O.O.,Babalola O.O. .2018 .The influence of plant growth promoting rhizobacteria in plant tolerance. Applied Microbiology and Biotechnology, 102(18) : 7821-7835.
[24] Anzuay S.,Ciancio M.G.R.,Ludueña L.,Ludueña L.,Angelini J.G.,Barros G.G.,Pastor N.,Taurian T. .2017 .Growth promotion of peanut (Arachis hypogaea L.) and maize (Zea mays L.) plants by single and mixed cultures of eficient phosphate solubilizing bacteria that are tolerant to abiotic stress and pesticides. Microbiological Research, 199 : 98-109.
[25] M. Cardinale S.,Ratering C.,Suarez C.,A.M.Z. Montoya R.,Geissler-Plaum S.,Schnell S. .2015 .Paradox of plant growth promotion potential of rhizobacteria and their actual promotion efect on growth of barley (Hordeum vulgare L.) under salt stress. Microbiological Research, 181 : 22-32.
[26] Kasim W.A.,Gaafar R.M.,Abou-Ali R.M.,Omar M.N.,Hewait H.M. .2016 .Efect of biofilm forming plant growth promoting rhizobacteria on salinity tolerance in barley. Annals of Agricultural Sciences, 61(2) : 217-227.
[27] Gamez R.,Cardinale M.,Montes M.,Ramirez S.,Schnell S.,Rodriguez F. .2019 .Screening, plant growth promotion and root colonization pattern of two rhizobacteria (Pseudomonas fluorescens Ps006 and Bacillus amyloliquefaciens Bs006) on banana cv. Williams (Musa acuminata Colla). Microbiological Research, 220 : 12-20.
[28] Rezaei-Chiyaneh R.,Amirnia M.A.,Machiani A.,Javanmard F.,Maggi M.R.,Morshedloo M.R. .2020 .Intercropping fennel (Foeniculum vulgare L.) with common bean (Phaseolus vulgaris L.) as afected by PGPR inoculation: A strategy for improving yield, essential oil and fatty acid composition. Scientia Horticulturae, 261 : 108951.
[29] Prasetyo R.H.,Setyobudi P.G.,Adinurani Z.,Vincēviča-Gaile A.,Fauzi T.A.,Pakarti R.,Tonda N.V.,Minh M.,Mel M. .2022 .Assessment of soil chemical properties for monitoring and maintenance of soil fertility in Probolinggo, Indonesia. Proceedings of the Pakistan Academy of Sciences: Part B, 59(4) : 99-113.
[30] .2023 .[Sumenep Regency in ifgures 2022]. pdf (accessed 19 May, : .
[31] Mathimaran N.,Jegan S.,Thimmegowda M.N.,Prabavathy V.R.,Yuvaraj P.,Kathiravan R.,Sivakumar M.N.,Manjunatha B.N.,Bhavitha N.C.,Sathish A.,Shashidhar G.C.,Bagyaraj D.J.,Ashok E.G.,Singh D.,Kahmen A.,Boller T.,Mäder P.N. .2020 .Intercropping transplanted pigeon pea with finger millet: Arbuscular mycorrhizal fungi and plant growth promoting rhizobacteria boost yield while reducing fertilizer input. Frontiers in Sustainable Food Systems, 4 : 1-12.
[32] Zechmeister-Boltenstern ,Scinner F.,Ohlinger R.,Kandeler E .1996 .Nitrogenase activity by acetylene reduction. , : .
[33] .2016 .Perancangan dan Analisis Data Percobaan Agro; Manual dan SPSS. [Design and Analysis of Agrotrial Data: Manual and SPSS]. , 1159798 : .
[34] Adinurani. Statistika Terapan P.G. .2022 .Agroteknologi (disusun sesuai rencana pembelajaran semester). [Agrotechnology Applied Statistics (compiled according to the semester learning plan)]. , 3 : .
[35] Banerjee A.,Sanyal S.,Sen S. .2012 .Soil phosphatase activity of agricultural land: A possible index of soil fertility. Agricultural Science Research Journals, 2(7) : 412-419.
[36] A.C.N. Boukhelata Y.,Kaci O.,Abrous-Belbachir O.,Djebbar R. .2019 .Isolation and identification of a phosphate-solubilizing Paenibacillus polymyxa strain GOL 0202 from durum wheat (Triticum durum Desf.) rhizosphere and its efect on some seedlings morphophysiological parameters. Biocatalysis and Agricultural Biotechnology, 19 : 101087.
[37] Panhwar Q.A.,Radziah O.,Naher U.A.,Shamshuddin J.,M.I. Razi. J. .2013 .Application of potential phosphate-solubilizing bacteria and organic acids on phosphate solubilization from phosphate rock in aerobic rice. The Scientific World Journal, 272409 : .
[38] Wang Z.,Chen Z.,Fu X. .2019 .Integrated efects of co-inoculation with phosphate-solubilizing bacteria and n2-fixing bacteria on microbial population and soil amendment under C deficiency. International Journal of Environmental Health Research, 16 : 2442.
[39] Yadav A.,Yadav K.,Vashistha A. .2016 .Phosphate solubilizing activity of Pseudomonas fluorescens PSM1 isolated from wheat rhizosphere. Journal of Applied and Natural Science, 8(1) : 93-96.
[40] Sharma R.Z.,Sayyed M.H.,Trivedi T.A.,Gobi T.A. .2013 .Phosphate solubilizing microbes: Sustainable approach for managing phosphorus deficiency in agricultural soils. Springer Plus, 587(1) : .
[41] Qiu S.,McComb A.J.,Bell R.W. .2008 .Ratios of C, N and P in soil water direct microbial immobilisationmineralisation and N availability in nutrient amended sandy soils in southwestern Australia. Agriculture, Ecosystems and Environment, 127(1- 2) : 93-99.
[42] Raymond N.S.,Gómez-Muñoz B.,Bom F.J.T. van der,Nybroe O.,Jensen L.S.,Müller-Stöver D.S.,Oberson A.,Richardson A.E.N.S. .2021 .Phosphatesolubilising microorganisms for improved crop productivity: A critical assessment. New Phytologist, 229(3) : 1268-1277.
[43] M. Saha B.R.,Maurya V.S.,Meena I.,Kumar A. .2016 .Identification and characterization of potassium solubilizing bacteria (KSB) from Indo-Gangetic Plains of India. Biocatalysis and Agricultural Biotechnology, 7 : 202-209.
[44] Etesami S.,Emami H.A.,Alikhani H.A. .2017 .Potassium solubilizing bacteria (KSB): Mechanisms, promotion of plant growth, and future prospects - A review. Journal of Plant Nutrition and Soil Science, 17(4) : 897-911.
[45] Weselowski B.,Nathoo N.,Eastman A.W.,Yuan Z.C. .2016 .Isolation, identification and characterization of Paenibacillus polymyxa CR1 with potentials for biopesticide, biofertilization, biomass degradation and biofuel production. BMC Microbiology, 16 : 244.
[46] Hu C.A.M.,Robert S.,Cadot X.,Zhang M.,Ye B.,Li D.,Manzo N.,Chervet T.,Steinger M.G.A. van der,Heijden K.,Schlaeppi M.,Erb M. .2018 .Root exudate metabolites drive plant-soil feedbacks on growth and defense by shaping the rhizosphere microbiota. Nature Communications, 9 : 2738.
[47] M.K. Hassan J.A.,McInroy and J.W.,Kloepper and J.W. .2019 .The interactions of rhizodeposits with plant growth promoting rhizobacteria in the rhizosphere: A Review. Agriculture, 142(7) : .
[48] Rao D.,Aparna K.,Mohanty S.R. .2019 .Microbiology and biochemistry of soil organic matter, carbon sequestration and soil health. Indian Journal of Fertilizers, 15(2) : 124-138.
[49] Costa O.Y.A.,Raaijmakers J.M.,Kuramae E.E. .2018 .Microbial extracellular polymeric substances: Ecological function and impact on soil aggregation. Frontiers in Microbiology, 9 : 1636.
[50] Rotaru V. .2015 .Responses of acid phosphatase activity on the root surface and rhizospheric soil of soybean plants to phosphorus fertilization and rhizobacteria application under low water supply. Scientific Papers. Series A. Agronomy, 50(8) : 295-300.
[51] C.S.R.M. Grover S.,Kundu S.,Desai S. .2017 .Soil enzymes. In: Encyclopedia of Soil Science, 3rd Edition, : 2100-2107.
[52] Shiroma T.,Moro H.,Sumi H. .2018 .Annual variation in soil enzyme activity in a paddy ifeld: Soil temperature and nutrient availability are important for controlling enzyme activities. Applied and Environmental Soil Science, 4093219 : .
[53] Zheng Y.,Liu J.,Zhang Y.,Chen L.,Yang H.,Li L.,Wang L. .2018 .Factors influencing soil enzyme activity in China's forest ecosystems. Plant Ecology, 219(1) : 31-44.
[54] Qu Y.,Tang J.,Li Z.,Zhou Z.,Wang J.,Wang S.,Chao Y. .2020 .Soil enzyme activity and microbial metabolic function diversity in soda saline-alkali rice paddy fields of northeast China. Sustainability, 10095(23) : .
[55] Benedetto N.A.D.,Corbo M.R.,Campaniello D.,Cataldi M.P.,A M.P.,Sinigaglia M.,Flagella Z. .2017 .The role of plant growth promoting bacteria in improving nitrogen use eficiency for sustainable crop production: A focus on wheat. AIMS Microbiology, 3(3) : 413-434.
[56] R.F.D. Almeida E.R.,Naves R.,Pinheiro D.,Mota D. .2015 .Soil quality: Enzymatic activity of soil β-glucosidase. Global Journal of Agricultural Research and Reviews, 3(2) : 2437-1858.
[57] Kausar R.,Choudary M.I.,Akram M.I.,Rashid M.,Rehman O.U,Malik A.,Khalid M.A.U.R.,Zubair M.,Alvi S. .2018 .Response of groundnut (Arachis hypogaea L.) to plant growth promoting Rhizobacteria in degraded soils. African Journal of Agricultural Research, 13(17) : 904-910.
[58] Lima J.V.,Tinôco R.S.,Olivares F.L.,A.J.G. de Moraes G.S.,Chia G.S. .2020 .Hormonal imbalance triggered by rhizobacteria enhance nutrient use eficiency and biomass in oil palm. Scientia Horticulturae, 264 : 109161.
[59] Muscolo S.M.N.A.,Panuccio M.R.,Zahir Z.,Mahmood S. .2019 .Use of plant growth-promoting rhizobacteria to ameliorate the performance of lentil under salinity. Journal of Applied Botany and Food Quality, 92 : 179-186.
[60] R.B.S. Nabi R.,Shahzad R.,Tayade M.,Shahid A.,Hussain M.W.,Ali B.,Yun B. .2021 .Evaluation potential of PGPR to protect tomato against fusarium wilt and promote plant growth. Peer J, 16(9) : .
[61] M. Grover S.,Bodhankar A.,Sharma P.,Sharma J.,Singh L. Nain. .2021 .PGPR mediated alterations in root traits: Way toward sustainable crop production. Frontiers in Sustainable Food Systems, 4 : 618230.
[62] Kapali S.,Gade R.M.,Shitole A.V.,Aswathi S. .2016 .Isolation and characterization of Pseudomonas lfuorescens and Bacillus subtilis and their in vitro evaluation. Advances in Life Sciences, 5(16) : 5856-5859.
[63] B.M. Bajracharya C.M.,Smeaton I.,Markelov E.,Markelova C.,Lu O.A.,Cirpka P. Van,Capellen P. Van .2022 .Organic matter degradation in energylimited subsurface environments - A bioenergeticsinformed modeling approach. Geomicrobiology Journal, 39(1) : 1-16.
[64] Reischke S.,Kumar M.G.K.,Bååth E. .2015 .Threshold concentration of glucose for bacterial growth in soil. Soil Biology and Biochemistry, 80 : 218-223.
[65] Kaushal R.,Sharma V.,Chaudhary S.,Dhaliwal S.S.,Alsuhaibani A.M.,Gaber A.,Hossain A. .2023 .Evaluation of the usefulness of fermented liquid organic formulations and manures for improving the soil fertility and productivity of brinjal (Solanum melongena L.). Agriculture, 417(2) : .
[66] Nguyen H.T.,Kappas M. .2018 .Assessment of soil quality indicators under diferent agricultural land uses and topographic aspects in Central Vietnam. International Soil and Water Conservation Research, 6(4) : 280-288.
[67] Bünemann E.K.,Brussaard L.,Mäder P.,Oguejiofor C.U.,R.G.M. de Goede C.U. .2020 .Soil management intensity shifts microbial catabolic profiles across a range of European long-term field experiments. Applied Soil Ecology, 154 : 103596.
[68] D.H. Goenadi R.H.,Setyobudi E.,Yandri K.,Siregar A.,Winaya D.,Damat W.,Widodo A.,Wahyudi P.G.,Adinurani M.,Mel M.Z.,Mazwan D.D.,Siskawardani E.D.,Purbajanti and I. Ekawati. .2021 .Land suitability assessment and soil organic carbon stocks as two keys for achieving sustainability of oil palm (Elaeis guineensis Jacq. Sarhad Journal of Agriculture, 37(1) : 184-196.
[69] I.K. Sumantra I.K.,Widnyana N.G.A.E.,Martingsih I.M.,Tamba P.G.,Adinurani M.,Mel P.,Soni P. .2023 .Agronomic characters and quality of fruit of salak cv. gulapasir planted in various agroecosystems. Jordan Journal of Biological Science, 16(2) : 207-221.
[70] Pramulya R.,Bantacut T.,Yani M.,Zulfajrin M.,Setiawan Y.,Pulunggono H.B.,Sudrajat S.,Anne O.,Anwar S.,Adinurani P.G.,Siregar K.,Prasetyo H.,Harsono S.S.,Novita E.,D.M Rahmah N.N.,Huu D.,Agustia M.I. Rasyid. .2023 .Carbon footprint calculation of net CO2 in agroforestry and agroindustry of Gayo Arabica cofee. Jordan Journal of Biological Sciences, 16(2) : 335-343.
[71] Negi R.,Kaur T.,Devi R.,Kour D.,Yadav A.N. .2022 .Assessment of nitrogen-fixing endophytic and mineral solubilizing rhizospheric bacteria as multifunctional microbial consortium for growth promotion of wheat and wild wheat relative Aegilops kotschyi. Heliyon, 8(12) : .
[72] Destari D.N.,Koentjoro M.P.,I. Ekawati M.P.,Prasetyo E.N. .2021 .Pre-evaluation of urease production by Bacillus sp. SK II-5 thermophilic bacteria using agricultural waste as a substrate. IOP Conference Series: Earth and Environmental Science, 649(012030) : .
[73] Susanto R.H.,Setyobudi D.,Sugiyanto S.M.,Nur H.,Herianto Y.,Jani S.K.,Wahono P.G.,Adinurani Y.,Nurdiansyah Y.,Yaro A. .2019 .Development of the biogas-energized livestock feed making machine for breeders. E3S Web of Conferences, 188 : 00010.
[74] Setyobudi R.H.,Wahono S.K.,Mel M.,Nindita A.,Purbajanti E.,Harsono S.S.,Malala A.R.,Nelwan L.O.,Sasmito A. .2017 .Ballast weight review of capsule husk Jatropha curcas Linn. on acid fermentation first stage in two-phase anaerobic digestion. Proceedings of the Pakistan Academy of Sciences: Part B, 54(1) : 47-57.
[75] R.H. Setyobudi A.,Sasmito P.G.,Adinurani A.,Nindita A.S.,Yudhanto Y.A.,Nugroho T.,Liwang M.,Mel M. .2015 .The study of slurry recirculation to increase biogas productivity from Jatropha curcas Linn. capsule husk in two phase digestion. Energy Procedia, 65 : 300-308.
[76] Nelwan L.O.,Sakri Y.,Wahono S.K.,Setyobudi R.H. .2013 .The study of two stages anaerobic digestion application and suitable bio-film as an efort to improve bio-gas productivity from Jatropha curcas Linn capsule husk. Energy Procedia, 32 : 84-89.
[77] Anukam A.I.,Nyamukamba P.,Treatment. M.K. Meghvansi Human Waste,A.K. Human Waste .2022 .and. Environmental and Microbial Biotechnology, : 29-38.
[78] Somorin T.O.,Prospects. M.O. Daramola Future,Ayeni A.O. .2020 .and. Green Energy and Technology, : 341-370.
[79] J. Burlakovs Z.,Vincevica-Gaile V.,Bisters W.,Hogland M.,Kriipsalu I. Zekker,Jani Y.,Anne O. .2022 .Application of anaerobic digestion for biogas and methane production from fresh beach-cast biomass. Proceedings EAGE GET 2022 - 3rd Eage Global Energy Transition, : 1-5.
[80] Yandri B.,Novianto F.,Fridolini R.H.,Setyobudi H.,Wibowo S.K.,Wahono K.,Abdullah W.,Purba Y.A.,Nugroho Y.A. .2021 .The technical design concept of hi-tech cook stove for urban communities using non-wood agricultural waste as fuel sources. E3S Web of Conferences, 226(00015) : .
[81] Benyahya Y.,Fail A.,Alali A.,Sadik M. .2022 .Recovery of household waste by generation of biogas as energy and compost as bio-fertilizer-A Review. Processes, 81(1) : .
[82] Barłóg P.,Hlisnikovský L.,Kunzová E. .2020 .Efect of digestate on soil organic carbon and plantavailable nutrient content compared to cattle slurry and mineral fertilization. Agronomy, 379(3) : .
[83] Jasiński T.,Grzelak M.,Witaszek K.,Dach J. .2022 .Biogas plant operation: Digestate as the valuable product. Energies, 8275(21) : .
[84] Baştabak B.,Koçar G. .2020 .A review of the biogas digestate in agricultural framework. Journal of Material Cycles and Waste Management, 22 : 1318-1327.
[85] Rahayu S.,Purbajanti E.D.,Siskawardani D.D.,Stankeviča K.,Setyobudi R.H. .2021 .Enhanced of root nodules, uptake NPK, and yield of peanut plant (Arachis hypogaea L.) using rhizobium and mycorrhizae applications. Sarhad Journal of Agriculture, 37(1) : 16-24.
[86] Raya-Hernández A.I.,Jaramillo-López P.F.,López-Carmona D.A.,Díaz T.,Carrera-Valtierra J. A.,Larsen J. .2020 .Field evidence for maize-mycorrhiza interactions in agroecosystems with low and high P soils under mineral and organic fertilization. Applied Soil Ecology, 149 : 103511.
[87] Bijalwan P.,Jeddi K.,Sharma M.,Kaushik P.,Hessini K. .2021 .Mitigation of saline conditions in watermelon with mycorrhiza and silicon application. Saudi Journal of Biological Sciences, 28(7) : 3678-3684.
[88] Malhi G.S.,Kaur M.,Kaushik P.,Alyemeni M.N.,Alsahli A.A.,Ahmad P. .2021 .Arbuscular mycorrhiza in combating abiotic stresses in vegetables: An eco-friendly approach. Saudi Journal of Biological Sciences, 28(2) : 1465-1476.