Research Article

Isolation and Identification of Pink-Pigmented Facultative Methylotrophic Bacteria (PPFM) from the North Rumaila Field, Iraq

Anwar A. Maki* and Asaad M.R. Al-Taee

Department of Biological Development, Marine Science Center, University of Basrah, Basra, Iraq.

Received | January 08, 2025; Revised | February 07, 2025; Accepted | February 13, 2025; Published | February 25, 2025

*Correspondence | Anwar A. Maki, Department of Biological Development, Marine Science Center, University of Basrah, Basra, Iraq; Email: [email protected]

Citation | Maki, A.A. and A.M.R. Al-Taee. 2025. Isolation and identification of pink-pigmented facultative methylotrophic bacteria (PPFM) from the North Rumaila field, Iraq. Novel Research in Microbiology Journal, 9(1): 41-50.

DOI | https://dx.doi.org/10.17582/journal.NRMJ/2025/9.1.41.50

Keywords | Aliphatic hydrocarbons, Aromatic hydrocarbons, Biodegradation, Methylorubrum pseudosasae, 16S rDNA gene, MxaF gene

Copyright: 2025 by the authors. Licensee ResearchersLinks Ltd, England, UK.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Introduction

One type of the genus Methylobacterium is the pink-pigmented facultative methylotroph (PPFM). This bacterium can exploit one carbon compounds such as methanol, formate, formaldehyde, and other multi-carbon substrates as the main energy source. Methylobacterium belongs to phylum Pseudomonadota; class Alphaproteobacteria; order Hyphomicrobiales; Family Methylobacteriaceae (Ashok et al., 2020; Alessa et al., 2021). PPFM usually exist in several environments, including soil, water, and plants. Nonpathogenic bacteria for human and animals. In general, these methylotrophic bacteria are rod- shaped, Gram negative, and obligate aerobes (Palberg et al., 2022).

Some methylobacterial species support plant health via stimulating growth and preventing the pathogens infection (Someya et al., 2021). Moreover, PPFM may assist in mitigating the global warming through consuming greenhouse gases as CO2 and methane, and metabolizing methanol from plant leaves, contributing to the carbon cycle (Mondal et al., 2024). These bacteria possess the ability to oxidize methanol via the enzyme methanol dehydrogenase (MDH) that is encoded by the MxaF gene and acts as a marker for identifying this group of bacteria (Valdivia-Anistro et al., 2022).

In accordance with the presence of Methylobacterium sp. in contaminated hydrocarbons soil reported in several previous studies (Srivastva et al., 2017; Yang et al., 2018), many recent studies have exploited this character and used the bacteria in several applications such as crude oil biodegradation and environmental bioremediation (Maki et al., 2023, 2024). Since the introduction of oil and its byproducts, pollutants from these substances have created serious environmental concern (Hentati et al., 2021; Wu et al., 2023).Accidental crude oil spills formed during exploration, transportation, and use has extremely adverse effects on the ecosystem, contaminating water and soil (Zargar et al., 2022). Oil in soil leads to severe pollution characterized by low mineral nutrients levels and high concentration of hydrocarbon compounds (Rahayu et al., 2019). The primary aim of oil spill cleanup is to reduce or eliminate the toxic and/or the hazardous components, allowing the flora and the fauna such as single-cell organisms to enter the food chain. Bioremediation has emerged as one of the utmost hopeful treatment solutions for secondary oil removal (Sayed et al., 2021).

Bacteria can use organic pollutants as the sole carbon source and break them down in the soil. Biological degradation of crude oil in the soil is supported by several enzymes such as monooxygenase, dioxygenase, cytochrome P450, peroxidase, hydroxylase, and dehydrogenase (Sui et al., 2021). The only decisive factor for deterioration is the survival of bacteria in environments heavily contaminated with oil. Due to the ability of bacteria to decompose various hydrocarbon components, they are considered the best active decomposers of crude oil (Das et al., 2023). Many petroleum hydrocarbons released into the environment are broken down or metabolized by naturally occurring microorganisms in the environment (Žvirgždas et al., 2023). Native bacterial isolates for bioremediation of contaminants are preferred because they are more resistant to local environmental and geographic conditions and pose fewer routine obstacles to approved implementation (Muliadi et al., 2020). In this study, our objective was to isolate and identify the PPFM and evaluate their ability to biodegrade petroleum compounds.

Materials and Methods

Study area and sampling

Ten Soil samples were collected from the North Rumaila oil field at the coordinates of 30°34ʹ11.6ʺ N latitude and 47°18ʹ22.7ʺ E longitude. Rumaila field is the largest oil field in Iraq, located 50 km west of Basra and covering an area of 1,800 km2. It was discovered in 1953 and became operational in 1972. With oil reserves of about 17 billion barrels, it ranks sixth in the world. Soil samples were taken and collected using a sterilized trowel from the well cellar at 5–10 cm depth, put in polythene bags, and transferred to the lab, where they were stored at 4 °C until further analysis. The crude oil used in the study was obtained from Al-Shaeba refinery, Basra, Iraq.

Isolation and characterization of PPFM

PPFM bacteria were isolated as described by Maki et al. (2023), i.e., 1.0 g of soil sample was added to a mineral salt medium (MSM) with 1% methanol and incubated for 7 days at 30 °C and 180 rpm. A 50-µL portion was spread onto MSM agar plates and incubated for 5 days at 30 °C. All the colonies that were grown were examined and purified for cell morphology, Gram staining, and genetic identification.

Identification of methylotrophic using 16S rDNA

The genomic DNA of the methylotrophic bacteria was isolated using the G-spin™ Genomic DNA Extraction Kit (iNtRON, Korea, Cat. No. 17121) following the manufacturer’s protocol. Genetic amplification of the 16S rDNA gene was carried out on a thermocycler (Eppendorf, Germany) using the universal primer sets 27F AGAGTTTGATCCTGGCTCAG and 1492R GGTTACCTTGTTACGACTT. The 25 µL PCR reaction mix, which included a master mix of 12.5 µL of GoTaq Green master mix (Promega, USA), 2 µL of bacterial DNA, 2 µL of each primer, and 6.5 µL of nuclease-free water, was subjected to initial denaturation at 95 °C for 5 min, followed by 35 cycles of 95 °C for 30 s, 55 °C for 30 s, 72 °C for 1 min, and a final extension at 72 °C for 5 min for 16S rDNA amplification genes (Maki et al., 2024).

Following DNA amplification, Sanger sequencing was performed. The sequences were aligned and compared to 16S rDNA sequences of bacterial isolates available in the National Centre for Biotechnology Information (NCBI) nucleotide database (http://www.ncbi.nih.gov/blast). The isolated bacteria were identified based on the maximum percentage similarity of the sequences.

Detection of MxaF gene

Specific primers for the MxaF gene were used to detect the methylotrophic bacteria. The primer sequences were F1003degen 5ʹ- GGNCANACYTGGGGNTGGT-3ʹ and R1561degen 5ʹ-GGGARCCNTTYATGCTNCCN-3ʹ (Maki et al., 2024).

Pink pigment facultative methylotrophic (PPFM) bacterial growth assessment

One ml of each bacterial culture suspension was added to a conical flask containing 100 ml of MSM with 1 g of crude oil (3 replicates). All flasks were incubated for 10 d at 30 °C and 120 rpm in addition to bacteria free flask as controls (Maki et al., 2023). After incubation, the optical density (600 nm) of the growth was measured daily using spectrophotometer, Beckman coulte DU530, UK.

Oil biodegradation and gas chromatography (GC) analysis

Two conical flasks each containing 100 ml of MSM with 1% (v/v) crude oil were inoculated with 1 ml of bacterial suspnsion in the logarithmic phase simultaneously with a bacteria-free flask as a control. All flasks were incubated at 30 °C and 120 rpm. After 5 and 10 days of incubation, the remaining crude oil was extracted and separated into aliphatic and aromatic fractions. A liquid-liquid extraction technique (Maki et al., 2024) was used to extract the excess crude oil. Gas chromatography (GC) analysis was used to detect the aromatic and aliphatic fractions. GC reports were used to calculate the percentage (%) of oil biodegradation.

Results

Pink pigment facultative methylotrophic (PPFM) bacterial isolation and characterization

The pink pigment facultative methylotrophic (PPFM) bacteria were isolated (11 isolate) according to their ability to grow on a MSM medium containing methanol as the sole source of carbon and nitrogen, in addition to their ability to form pink colonies (Figure 1). Under the light microscope, examination revealed that the cells were rod-shaped and Gram-negative.

 

Identification of the selected methylotrophic bacterium via 16S rDNA amplification using polymerase chain reaction (PCR)

Sequence analysis of the 16S rDNA gene was conducted based on sequence homology with those in the NCBI. The molecular identity of the selected bacterial isolate was Methylorubrum pseudosasae (NCBI Gene Bank accession no. OR226418.1) with 98% similarity.

MxaF gene detection

The MxaF gene was amplified with specific primers for this selected bacterium to further confirm that the bacterium belonged to the methylotrophic group. The gene was amplified and detected as a single band of 550 bp (Figure 2).

 

 

Pink pigment facultative methylotrophic bacterium growth assessment

A significant increase in bacterial cell density was detected (using spectrophotometer at OD 600) accompanied by a decrease in several components of the spent crude oil after 10 d of incubation on a medium containing crude oil as shown Figure 3. The optical density reached 0.7 after 5 d and dropped to 0.2 after 10 d of incubation.

Biodegradation and gas chromatography (GC) analysis of n-alkane

Gas Chromatography (GC) analysis of saturated crude oil revealed numerous peaks above the hump, representing the n-alkane hydrocarbon. The crude oil sample studied as control had the saturated fraction at C10 to C40 (Figure 4a). The degradation of aliphatic compounds by M. pseudosasae strain AAZ2 was 65.45% after ٥ d of incubation (Figure 4b). Meanwhile, after ١٠ d of incubation, the residual content of used crude oil decreased to 74.6% (Figure 4c), with complete disappearance of the short chains C10 and C11 compared to the control.

Biodegradation and GC analysis of poly aromatic compounds (PAH)

The biodegradation percentage of PAH compounds by M. pseudosasae strain AAZ2 detected by GC was 94.77% after 5 d of incubation compared to the control (Figure 5a). The degradation rates of fluorene, pyrene, benzo (A) anthrac, and benzo (B) fluora were 92.16%, 95.05%, 95.82%, and 91.68%, respectively. Meanwhile, benzo (K) fluora and benzo (A) pyrene yielded 88.6% and 89.79%, respectively. Interestingly, the 2-methylnaphtha, acenaphthene, acenaphthyene phenathrene, anthracene, chrysene, and indeno (1, 2, 3-CD) fractions were completely (100%) degraded (Figure 5b).

 

 

After 10 d of incubation, the residual spent crude oil content decreased to 98.11% (Figure 5c), almost completely disappearing compared to the control. The degradation rates of phenanthrene, fluorene, pyrene, benzo (B) fluorine, and benzo (K) fluorene were 95.26%, 90.92%, 94.74%, 97.74%, and 96.84%, respectively. In contrast, the fractions of 2-methylnaphtha, acenaphthene, acenaphthylene, anthracene, chrysene, benzo (A) pyrene, benzo (A) anthra, and indene (1, 2, 3-CD) were completely (100%) degraded.

Discussion

The isolated bacterial strain was putatively identified as a methylotrophic bacterium due to its growth on the medium containing methanol as the sole carbon source, which was confirmed by PCR analysis. Methanol is known to be a key substrate for many methylotrophic microbial species (Kolb, 2009). Pairs of universal primers for the16S rDNA gene were used to identify the PPFM bacterium. Molecular identification was performed using PCR, which is currently used as a sensitive and specific method for characterization (Aladwan et al., 2024).

Using the 16S rRNA gene sequence, the isolate was identified as Methylorubrum pseudosasae. Known to be facultatively methylotrophic, this bacterium is capable of utilizing methanol, dichloromethane, and methylamine as substrates (Green and Ardley, 2018). Specific primers were used to amplify the methanol dehydrogenase gene MxaF obtained from M. pseudosasae DNA, highlighting the importance of C1 metabolism (Figure 2). In a previous study reported by Kumar et al. (2019), PPFM were tested for the presence of the MxaF gene, confirming this gene as a key functional marker for identifying these bacterial types. The methanol dehydrogenase enzyme is essential for oxidizing methanol to formaldehyde and among several types of methanol dehydrogenases found in the methylotrophic bacteria, MxaF has been shown to perform optimally (Macey et al., 2020). However, there are no previous reports of isolating these bacteria from soil contaminated with petroleum hydrocarbons.

In the current study, it was found that M. pseudosasae had the ability to grow in a medium containing crude oil as the sole source of energy and carbon. Meanwhile several previous studies revealed that various species of the Methylorubrum genus were isolated from different parts of plants, including soybean, palm oil, banana (Ishak et al., 2021; Senthilkumar et al., 2021; Christian et al., 2021), Cucurbita pepo, potato, rice, and (Eevers et al., 2015; Grossi et al., 2020; Lai et al., 2020).

On other hand few studies have isolated PPFM belonging to the Methylorubrum genus from oil-contaminated soils. Godini et al. (2018) study succeeded in isolating Methylobacterium persicinum from oil-polluted sites, where they managed to grow this strain in MSM medium containing 2% crude oil as the sole carbon source. Similarly, Rojas-Gätjens et al. (2022) isolated Methylorubrum rhodesianum as a methylotrophic bacterium from the oil well and exploited it to consume methanol as the sole carbon source. Meanwhile, Harumain et al. (2023) study isolated Methylobacterium sp from the sludge of an oil refinery and Maki et al. (2023) isolated Methylorubrum extorquens from oil-contaminated soil in the Al-Zubair oilfield, Iraq, which was able to grow on MSM medium supplemented with 1% crude oil.

Additionally, the current study showed that M. pseudosasae had the ability to degrade aliphatic hydrocarbons with short chains that were completely removed from the broth medium. Biodegradation targets alkanes with a lower carbon chain (C10), as they are more susceptible to microbial attack and are therefore easier to degrade (Liu et al., 2020). This aligns with the previous study reported by Salam et al. (2015), who revealed that used motor oil was degraded by Methylobacterium mesophilicum by 61.2% after 12 d and 89.5% after 21 d of incubation. Similarly, Harumain et al. (2023) demonstrated that after 15 d of incubation, every aliphatic n-alkane was efficiently degraded by the ZASH strain of Methylobacterium sp. According to a previous study conducted in Iraq by Maki et al. (2024), M. extorquens isolated from petroleum soil degraded 61.14% of the n-alkane after one week of incubation.

The current decomposition of PAH compounds produced largely successful gas chromatographic analysis results, in agreement with the previous findings reported by other researchers, Salam et al. (2015) identified how M. mesophilicum could be utilized to fractionally decompose PAH, particularly anthracene and pyrene. Meanwhile, Ventorino et al. (2014), Maki et al. (2023) illustrated the mode of PAH compounds decomposition using Methylobacterium populi and M. extorquens, respectively.

Conclusions and Recommendations

The findings of this study suggest that Methylorubrum pseudosasae can use methanol as its sole carbon source. Additionally, this bacterium had shown the ability to grow when both energy and carbon sources are available only from crude oil. Methylorubrum pseudosasae is capable of withstanding harsh and contaminated environments with high concentrations of oil compounds. Under in vitro conditions, this strain demonstrated the effectiveness of crude oil removal, indicating that this bacterium could potentially be used to decontaminated polluted environments directly on-site. we recommended that isolated new species of methylotrophic bacteria which have the ability to degrade hydrocarbons. Also, can use a new method of gene editing such as CRISPR Cas 9 to enhance the degradation of this bacterium.

Acknowledgments

The authors acknowledge the Marine Science Centre, University of Basrah, Iraq for assistance during the period of the study and Mr. Hassan A.N. Alshawi, Research and Quality Control, South Oil Basra, Iraq for his assistance in conducting the GC analysis.

Novelty Statement

On the basis of our acknowledge this is the first time isolating Methylorubrum pseudosasae from oil contaminated soil and employment in vitro to biodegradation of crude oil.

Author’s Contribution

Anwar A. Maki and Asaad M.R. Al-Taee: Conceptualization, data curation, investigation, supervision, validation, roles/writing original draft, writing review and editing.

Funding source

The present study did not receive any financial support.

Ethical approval

Non-applicable.

Conflict of interests

The authors have declared no conflict of interests.

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