MSc Marcin Musiałowski

MSc Marcin Musiałowski is a PhD candidate supervised by Dr Klaudia Dębiec-Andrzejewska, focusing on the role of bacterial metabolites (siderophores) in soil regeneration and sustainable agriculture. His research examines siderophore-producing bacteria, optimisation of culture media for metabolite production and the creation of biofertilizer formulations that enhance both chemical and biological soil parameters. His work demonstrates the potential of siderophore-based solutions to improve nutrient availability, support microbiome recovery and increase the efficiency of phytoremediation. He is specializing in genomic analysis of the soil microbiome.

Scientific interests

Environmental and agricultural microbiology
Microbial metabolites and biofertilizer development
Soil regeneration and nutrient mobilisation
Molecular microbiology and bacterial functional analysis
Microbial metabolite–based soil amendments
Optimisation of siderophore production

Publications

2025

Musiałowski, Marcin; Mierzwa-Hersztek, Monika; Gondek, Krzysztof; Dębiec-Andrzejewska, Klaudia

A novel two-step metabarcoding approach improves soil microbiome biodiversity assessment Journal Article

In: Sci Rep, vol. 15, no. 1, 2025, ISSN: 2045-2322.

Links | BibTeX

Jarosz, Renata; Klimkowicz-Pawlas, Agnieszka; Biel, Karolina; Mokrzycki, Jakub; Musiałowski, Marcin; Dębiec-Andrzejewska, Klaudia; Mierzwa-Hersztek, Monika

Effect of innovative mineral-organic mixtures on enzymatic activity, ecotoxicity, and microbial communities in contaminated soil Journal Article

In: Soil and Tillage Research, vol. 253, 2025, ISSN: 0167-1987.

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Salinitro, Mirko; Schiavon, Michela; Musiałowski, Marcin; Dębiec-Andrzejewska, Klaudia; Aarts, Mark G. M.; Padoan, Elio; Montanarini, Benedetta; Tassoni, Annalisa; van der Ent, Antony

From waste to value: agromining of nickel, cobalt, and selenium from mine waste amended with sewage sludge Journal Article

In: Plant Soil, 2025, ISSN: 1573-5036.

Abstract | Links | BibTeX

@article{Salinitro2025c,

title = {From waste to value: agromining of nickel, cobalt, and selenium from mine waste amended with sewage sludge},

author = {Mirko Salinitro and Michela Schiavon and Marcin Musiałowski and Klaudia Dębiec-Andrzejewska and Mark G. M. Aarts and Elio Padoan and Benedetta Montanarini and Annalisa Tassoni and Antony van der Ent},

doi = {10.1007/s11104-025-07924-3},

issn = {1573-5036},

year  = {2025},

date = {2025-10-17},

journal = {Plant Soil},

publisher = {Springer Science and Business Media LLC},

abstract = {Abstract

          

            Background and aims

            The global demand for critical elements such as nickel, cobalt, and selenium is projected to increase significantly, driven by the transition to renewable energy. Mine wastes and sewage sludge, often enriched with these elements, represent untapped secondary resources. Agromining, an emerging phytotechnology that employs hyperaccumulator plants to extract metals from contaminated or enriched soils, offers a sustainable recovery method. The aim of this study is to provide a crucial proof-of-concept for the recovery of the critical elements nickel, cobalt, and selenium from these alternative resources through agromining.

          

          

            Methods

            Mine wastes from three Italian mining sites were amended with sewage sludge at rates of 0, 15, and 30 kg m−2. Three hyperaccumulator species targeting cobalt, (Berkheya coddii), selenium (Astragalus bisulcatus) and nickel (Odontarrhena chalcidica) were grown on these wastes. Biogeochemical characterization of the substrate was performed before and after agromining. In addition, plant biomass and metal accumulation were monitored.

          

          

            Results

            Sewage sludge increased biomass across all species, especially in A. bisulcatus, but metal accumulation decreased by 33–60% for nickel, 0–41% for cobalt, and 67–74% for selenium. Furthermore, sewage sludge and agromining enhanced mine waste fertility and microbial diversity.

          

          

            Conclusions

            Agromining of sewage sludge-amended mine wastes shows potential for sustainable recovery of selenium and cobalt. However, high sewage sludge application increased plant biomass, but concurrently reduced plant tissue metal concentrations. This study underscores the importance of optimizing sewage sludge / mine waste ratios for successful agromining. 

          },

keywords = {},

pubstate = {published},

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Goszcz, Aleksandra; Furtak, Karolina; Stasiuk, Robert; Wójtowicz, Joanna; Musiałowski, Marcin; Schiavon, Michela; Dębiec-Andrzejewska, Klaudia

Bacterial osmoprotectants—a way to survive in saline conditions and potential crop allies Journal Article

In: vol. 49, 2025, ISSN: 1574-6976.

Abstract | Links | BibTeX

@article{Goszcz2025b,

title = {Bacterial osmoprotectants—a way to survive in saline conditions and potential crop allies},

author = {Aleksandra Goszcz and Karolina Furtak and Robert Stasiuk and Joanna Wójtowicz and Marcin Musiałowski and Michela Schiavon and Klaudia Dębiec-Andrzejewska},

doi = {10.1093/femsre/fuaf020},

issn = {1574-6976},

year  = {2025},

date = {2025-00-00},

volume = {49},

publisher = {Oxford University Press (OUP)},

abstract = {Abstract

               Soil salinization, affecting 6.5% of arable land, deteriorates soil properties, reduces microbiota activity, hinders plant growth, and accelerates soil erosion. Excessive salt induces physiological drought and toxicity stress in plants, causing chlorosis, ion imbalances, and enzyme disruptions. This paper discusses microorganisms’ resistance mechanisms, plant responses to salt stress, and summarizes current knowledge on bacterial osmoprotectants and their functions. It also reviews emerging agrobiotechnological strategies using microbial osmoprotectants to remediate salinized soils and enhance plant growth and productivity under salt stress. Osmoprotectants stabilize proteins, buffer redox potential, and retain water, thus alleviating osmotic stress and promoting bacteria and plants growth. Their application improves soil properties by enhancing aggregate formation, water permeability, moisture content, cation exchange capacity, and ion availability. Despite extensive literature on the function of osmoprotectants, the knowledge about their role in soil environments and agrobiotechnology applications remains limited. This paper indicates proposed research perspectives, including discovering new osmoprotectants, their correlation with soil fertilization, interactions with the soil microbiome, and plant responses. It also identifies significant knowledge gaps in these areas, highlighting the need for further studies to consolidate existing data and assess the potential of this approach to enhance soil health and crop productivity in saline environments.},

keywords = {},

pubstate = {published},

tppubtype = {article}

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2024

Vaccaro, Francesca; Passeri, Iacopo; Ajijah, Nur; Bettini, Priscilla; Courty, Pierre Emmanuel; Dębiec-Andrzejewska, Klaudia; Joshi, Namrata; Kowalewska, Łucja; Stasiuk, Robert; Musiałowski, Marcin; Pranaw, Kumar; Mengoni, Alessio

Genotype-by-genotype interkingdom cross-talk between symbiotic nitrogen fixing Sinorhizobium meliloti strains and Trichoderma species Journal Article

In: Microbiological Research, vol. 285, 2024, ISSN: 0944-5013.

Links | BibTeX

2023

Zakrzewska, Marta; Rzepa, Grzegorz; Musialowski, Marcin; Goszcz, Aleksandra; Stasiuk, Robert; Debiec-Andrzejewska, Klaudia

Reduction of bioavailability and phytotoxicity effect of cadmium in soil by microbial-induced carbonate precipitation using metabolites of ureolytic bacterium Ochrobactrum sp. POC9 Journal Article

In: Front. Plant Sci., vol. 14, 2023, ISSN: 1664-462X.

Abstract | Links | BibTeX

@article{Zakrzewska2023b,

title = {Reduction of bioavailability and phytotoxicity effect of cadmium in soil by microbial-induced carbonate precipitation using metabolites of ureolytic bacterium Ochrobactrum sp. POC9},

author = {Marta Zakrzewska and Grzegorz Rzepa and Marcin Musialowski and Aleksandra Goszcz and Robert Stasiuk and Klaudia Debiec-Andrzejewska},

doi = {10.3389/fpls.2023.1109467},

issn = {1664-462X},

year  = {2023},

date = {2023-06-21},

journal = {Front. Plant Sci.},

volume = {14},

publisher = {Frontiers Media SA},

abstract = {The application of ureolytic bacteria for bioremediation of soil contaminated with heavy metals, including cadmium (Cd), allows for the efficient immobilization of heavy metals by precipitation or coprecipitation with carbonates. Microbially-induced carbonate precipitation process may be useful also in the case of the cultivation of crop plants in various agricultural soils with trace but legally permissible Cd concentrations, which may be still uptaken by plants. This study aimed to investigate the influence of soil supplementation with metabolites containing carbonates (MCC) produced by the ureolytic bacterium Ochrobactrum sp. POC9 on the Cd mobility in the soil as well as on the Cd uptake efficiency and general condition of crop plants (Petroselinum crispum). In the frame of the conducted studies (i) carbonate productivity of the POC9 strain, (ii) the efficiency of Cd immobilization in soil supplemented with MCC, (iii) crystallization of cadmium carbonate in the soil enriched with MCC, (iv) the effect of MCC on the physico-chemical and microbiological properties of soil, and (v) the effect of changes in soil properties on the morphology, growth rate, and Cd-uptake efficiency of crop plants were investigated. The experiments were conducted in soil contaminated with a low concentration of Cd to simulate the natural environmental conditions. Soil supplementation with MCC significantly reduced the bioavailability of Cd in soil with regard to control variants by about 27-65% (depending on the volume of MCC) and reduced the Cd uptake by plants by about 86% and 74% in shoots and roots, respectively. Furthermore, due to the decrease in soil toxicity and improvement of soil nutrition with other metabolites produced during the urea degradation (MCC), some microbiological properties of soil (quantity and activity of soil microorganisms), as well as the general condition of plants, were also significantly improved. Soil supplementation with MCC enabled efficient Cd stabilization and significantly reduced its toxicity for soil microbiota and plants. Thus, MCC produced by POC9 strain may be used not only as an effective Cd immobilizer in soil but also as a microbe and plant stimulators.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

The application of ureolytic bacteria for bioremediation of soil contaminated with heavy metals, including cadmium (Cd), allows for the efficient immobilization of heavy metals by precipitation or coprecipitation with carbonates. Microbially-induced carbonate precipitation process may be useful also in the case of the cultivation of crop plants in various agricultural soils with trace but legally permissible Cd concentrations, which may be still uptaken by plants. This study aimed to investigate the influence of soil supplementation with metabolites containing carbonates (MCC) produced by the ureolytic bacterium Ochrobactrum sp. POC9 on the Cd mobility in the soil as well as on the Cd uptake efficiency and general condition of crop plants (Petroselinum crispum). In the frame of the conducted studies (i) carbonate productivity of the POC9 strain, (ii) the efficiency of Cd immobilization in soil supplemented with MCC, (iii) crystallization of cadmium carbonate in the soil enriched with MCC, (iv) the effect of MCC on the physico-chemical and microbiological properties of soil, and (v) the effect of changes in soil properties on the morphology, growth rate, and Cd-uptake efficiency of crop plants were investigated. The experiments were conducted in soil contaminated with a low concentration of Cd to simulate the natural environmental conditions. Soil supplementation with MCC significantly reduced the bioavailability of Cd in soil with regard to control variants by about 27-65% (depending on the volume of MCC) and reduced the Cd uptake by plants by about 86% and 74% in shoots and roots, respectively. Furthermore, due to the decrease in soil toxicity and improvement of soil nutrition with other metabolites produced during the urea degradation (MCC), some microbiological properties of soil (quantity and activity of soil microorganisms), as well as the general condition of plants, were also significantly improved. Soil supplementation with MCC enabled efficient Cd stabilization and significantly reduced its toxicity for soil microbiota and plants. Thus, MCC produced by POC9 strain may be used not only as an effective Cd immobilizer in soil but also as a microbe and plant stimulators.

Musiałowski, Marcin; Dębiec-Andrzejewska, Klaudia

Microbial Siderophores in Sustainable Applications—Preventing and Mitigating Effects of Climate Change Book Chapter

In: Bioinoculants: Biological Option for Mitigating global Climate Change, pp. 297–317, Springer Nature Singapore, 2023, ISBN: 9789819929733.

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