An Approach to Constructing Multispecies Biofilm Communities from Rhizosphere Soil

Summary

A rapid and standardized procedure for establishing synergistic multispecies biofilm communities from various rhizosphere soils is presented here. It is a unique protocol designed to probe and simulate the complex rhizosphere soil microbiota.

Abstract

The multispecies biofilm is a naturally occurring and dominant lifestyle of bacteria in nature, including in rhizosphere soil, although the current understanding of it is limited. Here, we provide an approach to rapidly establish synergistic multispecies biofilm communities. The first step is to extract cells from rhizosphere soil using the differential centrifugation method. Afterward, these soil cells are inoculated into the culture medium to form pellicle biofilm. After 36 h of incubation, the bacterial composition of the biofilm and the solution underneath are determined using the 16S rRNA gene amplicon sequencing method. Meanwhile, high-throughput bacterial isolation from pellicle biofilm is conducted using the limiting dilution method. Then, the top 5 bacterial taxa are selected with the highest abundance in the 16S rRNA gene amplicon sequencing data (pellicle biofilm samples) for further use in constructing multispecies biofilm communities. All combinations of the 5 bacterial taxa were quickly established using a 24-well plate, selected for the strongest biofilm formation ability by the crystal violet staining assay, and quantified by qPCR. Finally, the most robust synthetic bacterial multispecies biofilm communities were obtained through the methods above. This methodology provides informative guidance for conducting research on rhizosphere multispecies biofilm and identifying representative communities for studying the principles governing interactions among these species.

Introduction

Biofilms represent intricate microbial communities either affixed to surfaces or linked with interfaces. There is broad acknowledgment that the majority of bacteria encountered in various environments, such as natural habitats, clinical settings, and industrial contexts, endure within biofilm communities¹. In soil, the rhizosphere—encompassing the root surface and its adjacent 2 mm thick region—forms an ecological niche with heightened nutrient availability. Specific bacteria have evolved strategies to exploit this niche, fostering microbial proliferation and fostering the formation of biofilm communities in the rhizosphere².

Rhizosphere microbes are considered the 'second genome' of plants³. Plant growth-promoting microorganisms (PGPM) engage in mutualistic symbiosis with plants, providing significant growth promotion and biocontrol functions⁴. On the one hand, PGPM can supply nutrients to plant roots, enhance nutrient uptake, defend against pathogens, and degrade pollutants in the rhizosphere soil⁵. On the other hand, PGPM utilizes plant root exudates as a nutrient source for growth and evolution, thereby influencing the rhizosphere soil and root system through their own metabolism. It is worth noting that the prerequisite for all these functions is the effective colonization of PGPM in the plant rhizosphere, forming stable biofilms⁶.

Rhizosphere biofilm affects the assembly process of rhizosphere microbes, and the temporal and spatial characteristics of rhizosphere microbe assembly are closely related to the interaction of multispecies biofilm⁷. It serves as the hub of plant-microbiome interactions, providing a stable and controllable niche for them to interact effectively. Therefore, studying rhizosphere biofilm is also an important direction to gain insight into the interaction between plants and microbes.

However, there is currently little research on rhizosphere multispecies biofilms. The high complexity of microbiome composition makes it challenging to answer fundamental ecological questions surrounding natural microbial communities⁸. In the process of experiments, many conditions, such as soil type, plant type, and the large number of microbial communities, need to be considered. Various factors limit the research of rhizosphere multispecies biofilms.

To further investigate multispecies biofilm communities from rhizosphere soil, such as interspecies synergistic interactions or metabolite cross-feeding⁸, it is desirable to artificially construct a simplified, representative, stable, and tractable synthetic microbial community under laboratory conditions^9,10. Here, a standardized protocol combines several of the latest microbiological and bioinformatic techniques.

Protocol

This protocol is generally applicable to rhizosphere soil microbiota from various plants. Here, cucumber is used as an example. Details of the reagents and equipment used for the study are listed in the Table of Materials.

1. Bacterial isolation

1. Rhizosphere soil isolation
   1. Cucumber culture
      1. Disinfect cucumber seeds with 75% ethanol and 2% sodium hypochlorite (NaClO) solution, then rinse them in sterile water¹¹.
      2. Germinate the seeds under sterile conditions and select those that reach the two-leaf stage¹². Subsequently, transplant the consistently sprouted cucumber seedlings into pots containing 2 kg of black soil.
         NOTE: Two types of black soil from different locations in Northeast China are used to reduce systematic errors.
   2. Soil suspension preparation
      1. Prepare PBS-S buffer using the formulation: 6.33 g of NaH₂PO₄·H₂O, 16.5 g of Na₂HPO₄·7H₂O, 200 µL of Silwet L-77, and 1 L distilled water.
      2. When the seedlings reach the four-leaf stage¹², invert the pot and isolate the roots along with 2 mm-thick rhizosphere soil using sterilized gloves.
      3. Place the roots in 30 mL of PBS-S buffer in a 50 mL centrifuge tube. After shaking for 20 min, filter the suspension through a 100 µm nylon cell filter to remove roots and large sediments.
      4. Transfer the filtrate to another 50 mL centrifuge tube, centrifuge it at 3200 x g for 15 min at room temperature, and temporarily store it at 4 °C.
2. Extraction of rhizosphere soil bacterial cells.
   NOTE: This methodology adopts the differential centrifugation method¹³, although the Nycodenz density gradient centrifugation method¹⁴ also applies for this step.
   1. Dilute the soil suspension with a 0.2% Na₄P₂O₇ solution to 500 mL and centrifuge at 1,000 x g for 10 min to initially separate organisms from the soil.
   2. Re-homogenize the precipitate, centrifuge it at the same low speed for 60 s, and repeat the process three times. Combine the supernatants, centrifuge them at 12,000 x g for 20 min, and then discard the supernatant.
   3. Resuspend the precipitate in 50 mL of PBS-S buffer, constituting the rhizosphere soil bacterial cell suspension.

2. Sequencing and identification of rhizosphere biofilm microbiota

1. Media preparation
   NOTE: Tryptic soy broth (TSB) and Minimal salts glycerol glutamate (MSgg) media are commercially available. The formulations below are for reference only.
   1. Prepare TSB medium using the following formulation: 15 µg/mL tryptone, 5 µg/mL soy peptone, 5 µg/mL NaCl, pH = 7.
   2. Prepare MSgg medium using the following formulation: 5 mM KH₂PO₄, 100 mM 3-(N-morpholino) propane sulfonic acid (MOPS), 2 mM MgCl₂, 700 µM CaCl₂, 50 µM MnCl₂, 50 µM FeCl₃, 1 µM ZnCl₂, 2 µM thiamine, 0.5% glycerol, 0.5% glutamate, 50 µg/mL tryptophan, 50 µg/mL phenylalanine, pH = 7.
   3. To prepare TSB-MSgg media, mix TSB media with MSgg media in a 1:1 ratio (v/v)¹⁵.
2. Pellicle biofilm coculture
   1. Incubate the cell suspension in TSB medium at 30 °C overnight (usually 12 h) to activate the bacteria.
   2. Place 100 µm nylon cell filters on 24-well plates. Incubate the bacteria in TSB media and set up three repetitions. Cultivate the pellicle biofilm for 36 h at 30 °C.
      NOTE: If the pellicle biofilm from the last step is not well-cultivated, the TSB-MSgg medium is an effective substitute for the TSB medium.
   3. Remove the filter containing the pellicle biofilm. Add 2 mL of PBS-S buffer to a new 24-well cell plate, place the 24-well filter into it to wash the biofilm, and remove the free cells. Repeat the washing process three times.
3. Extraction of pellicle biofilm DNA
   1. Extract the biofilm genome using a DNA kit following the manufacturer's instructions.
4. High-throughput sequencing
   NOTE: Biotech companies can help complete sequencing experiments for most labs. If microbial composition in the remaining solution is needed, sequence it at this step. The sequencing step varies depending on the instruments. Please follow the manufacturer's instructions. Step 2.4.1 is for reference only.
   1. Amplify the V3-V4 regions of the 16S rRNA gene based on the database with full-length 16S rRNA gene sequences. Create species OTUs according to the minimum number of sequences per sample¹⁶. Cluster the species classification annotations and acquire the compositions of communities from each sample.
   2. Based on the sequencing data, select the top five strains in terms of their relative abundance.
5. High-throughput bacterial isolation and culture
   NOTE: This step is designed according to the latest microbiological and bioinformatic methodology¹⁷. The dilution-coated plate method is available for bacterial isolation here, although it is more time-consuming and less targeted compared to high-throughput techniques.
   1. Mix the cultivated biofilm. Use limiting dilution to ensure that no more than 30% of the wells in the 24-well plate show bacterial growth.
      NOTE: To determine the most suitable dilution, perform preliminary experiments using a wide range of dilution rates. The optimal dilution should contain no more than two culturable bacteria per milliliter, representing bacterial incubation in less than 30% of the wells.
   2. Amplify the 16S rRNA gene of the bacteria while adding labels for the wells and plates and sequence them using the high-throughput Illumina platform¹⁷.
   3. Conduct bioinformatic analyses using commercially available software to obtain purity and species taxonomic information for each culture.
   4. Cultivate the top five abundant pure bacteria by continuous line culture and use glycerol to preserve the bacteria at -80 °C.

3. Construction of synthetic microbial communities

1. Re-constructed biofilm culture
   NOTE: For details, please refer to Ren et al.¹⁸. The 5 strains correspond to 31 synthetic combinations, including 5 single-species, 10 two-species, 10 three-species, 5 four-species, and 1 five-species consortia.
   1. Incubate the 5 strains in the TSB medium until their OD₆₀₀ reaches 1 to activate them.
   2. Prepare several 24-well plates with TSB medium and place 100 µm nylon cell filters on them.
      NOTE: If the biofilm from the last step is not well-cultivated, the TSB-MSgg medium is an effective substitute for the TSB medium.
   3. Incubate the 31 combinations of synthetic communities in the medium. Ensure the inoculation number of bacteria is consistent in each well. Set up three repetitions for each combination.
   4. Cultivate the biofilm at 30 °C for 36 h.
2. Quantification of pellicle biofilm
   1. Follow the same procedure as in step 2.2.3.
   2. Transfer the biofilm to a new 24-well plate containing 180 µL of crystal violet solution and stain it for 20 min.
   3. Transfer the stained sample to another 24-well plate containing 200 µL of 96% ethanol, elute it for 30 min, and measure OD₅₉₀.

4. Pellicle cell number quantification

NOTE: To determine the proportion of each species and the cell counts in the pellicle and remaining solution, quantitative PCR is necessary. For details, refer to Sun et al.¹⁶.

1. Design strain-specific primers for the selected synthetic microbial communities.
2. Use Roary to perform genome comparisons and find out the strain-specific single-copy genes of each isolate. Ensure that primers are targeted to these genes.
3. Ligase the amplified fragments to PMD19T plasmids. Generate standard curves using the plasmids containing corresponding fragments as templates.
4. Follow the same steps as mentioned in step 2.2.
5. Prepare reaction components as follows: 7.2 µL of H₂O, 10 µL of 2x qPCR Master mix, 0.4 µL of 10 µM of each primer, and 2 µL template DNA.
6. Perform the PCR with a Real-time PCR Instrument under the following conditions: 95 °C for 10 min, 40 cycles of 95 °C for 30 s, and 60 °C for 45 s, followed by a standard melting curve segment.
7. Perform six biological replicates for each treatment.

Results

Following the mentioned procedure, significant gradients in biofilm-forming capacity from cucumber rhizosphere soil microbiota are observed (Figure 1). Biofilm amplicon sequencing confirmed the species in the pellicle (Figure 2). Based on the heat mapping of sequencing data, the top five bacterial species whose abundance in the pellicle is larger than that in the remaining solution were selected (Figure 3). Here, a typical group of ...

Discussion

Following the protocol, a series of robust synthetic multispecies biofilm communities are constructed based on the microbiota in rhizosphere soil from different plants. Using quantitative PCR techniques, the composition of each community is deciphered clearly. The biomass of the biofilm indicates the strength of their potential metabolic interactions, although various properties and mechanisms behind the cooperation could not be revealed here¹⁹. Given the size and complexity of natural microbial c...

Materials

Name	Company	Catalog Number	Comments
0.2 % Na4P2O7 solution	Sinopharm Chemical Reagent Co.,Ltd.	20041418	Used to dilute the soil suspension.
100 μm Nylon Cell Filter	Sangon Biotech (Shanghai) Co.,Ltd.	F613463-0001	Used to filter culture solution and separate pellicle biofilm.
2% NaClO solution	Sinopharm Chemical Reagent Co.,Ltd.	L03336903	Used to sterilize the seeds.
24-well Plate	Merck & Co., Inc.	PSRP010	Used for micobial cultivation and pellicle biofilm separation.
3-(N-morpholino) propane sulfonic acid (MOPS)	Bioolook Scientific Research Special	2360010	Used to prepare MSgg media.
50 mL Centrifuge Tube	Beijing Su-bio Biotech Co., Ltd.	62.547.254	Properly-sized centrifuge tubes for our protocol.
75% C2H5OH solution	Sinopharm Chemical Reagent Co.,Ltd.	801769680	Used to sterilize the seeds.
Acinetobacter baumannii XL-1	Nanjing Agricultural University	N/A	Strains isolated from rhizosphere soil.
Bacillus velezensis SQR9	Nanjing Agricultural University	N/A	Strains isolated from rhizosphere soil.
Bacteria DNA Kit	Nanjing Dinsi Biotechnology Co.,Ltd.	D3350020000K04U021	Used to extract bacterial DNA.
Black Soil I	Nanjing Agricultural University	N/A	Black soil from Jilin Province.
Black Soil II	Nanjing Agricultural University	N/A	Black soil from Heilongjiang Province.
Burkholderia cenocepacia XL-2	Nanjing Agricultural University	N/A	Strains isolated from rhizosphere soil.
CaCl2	Xilong Scientific Co.,Ltd.	10035048	Used to prepare MSgg media.
Centrifuge	Sangon Biotech (Shanghai) Co.,Ltd.	G508009-0001	High-speed centrifuge.
ChamQ SYBR qPCR Master Mix	Vazyme Biotech Co.,Ltd.	Q311-02	Used for DNA amplification in qPCR.
Clean Bench	Suzhou Antai Airtech Co., Ltd.	NB026143	Used for aseptic operation.
Constant Temperature Incubator	ShangHai CIMO Medical Instrument Co.,Ltd	GNP-9080BS-	Used for microbial cultivation.
Cristal Violet Dye	Sangon Biotech (Shanghai) Co.,Ltd.	A600331	Used for pellicle biofilm staining and quantifivation.
Cucumber Seed	Nanjing Agricultural University	N/A	"Jinchun I" cucumber seed.
Culturome v 1.0	The Institute of Genetics and Developmental Biology of the Chinese Academy of Sciences	N/A	Used for high-throughput rhizosphere soil bacterial cultivation and identification
FeCl3	Sinopharm Chemical Reagent Co.,Ltd	10011918	Used to prepare MSgg media.
Fridge	Hefei Midea Refrigerator Co.,Ltd.	BCD-556WKPM(Q)	Used for strain preservation.
Glutamate	Bioolook Scientific Research Special	2180020	Used to prepare MSgg media.
Glycerol	Sinopharm Chemical Reagent Co.,Ltd	10010618	Used to prepare MSgg media.
Hydroponic Planting Basket	Yulv Furniture Store	6526262626	Used for cucumber hydroponics.
KH2PO4	Xilong Scientific Co.,Ltd.	10017618	Used to prepare MSgg media.
MgCl2	Xilong Scientific Co.,Ltd.	7791186	Used to prepare MSgg media.
MnCl2	Xilong Scientific Co.,Ltd.	10400101	Used to prepare MSgg media.
Msgg Medium	Shanghai Bioesn Biotechnology Co.,Ltd.	BES20791KB	Pellicle biofilm culture medium.
Na2HPO4·7H2O	Merck & Co., Inc.	S9390-100G	Used to prepare TSB media.
NaCI	Chinasun Specialty Products co., Ltd.	HS0416	Used to prepare TSB media.
NaH2PO4·H2O	Merck & Co., Inc.	S9638-25G	Used to prepare TSB media.
PBS-S Buffer	Sangon Biotech (Shanghai) Co.,Ltd.	E607008-0001	Basic buffer for living tissues.
Phenylalanine	RYON	RT3486L005	Used to prepare MSgg media.
Pipette	Beijing Labgic Technology Co.,Ltd.	BS-1000-T	Used for strain inoculation.
PMD19T Plasmid	Takara Biomedical Technology (Beijing) Co.,Ltd.	D102A	Used to generate qPCR standard curves.
Pot	Sinopharm Chemical Reagent Co.,Ltd.	YHHWS2401	Used for cucumber soil culture.
Primer for qPCR	Sangon Biotech (Shanghai) Co.,Ltd.	N/A	Used for DNA amplification in qPCR.
Real-Time PCR Instrument	Thermo Fisher Scientific (China) Co.,Ltd.	4484073	Used to perform qPCR on selected pellicle biofilm.
Roary	The Wellcome Trust SangerInstitute	N/A	Used to design primers of qPCR
Shaker	Shanghai Zhichu Instrument Co.,Ltd	ZQTY-50S	Used for solution mixing and microbial cultivation.
Silwet L-77	Cytiva Bio-technology(Hangzhou) Co., Ltd.	SL77080596	Used to prepare TSB media.
Soy peptone	Qingdao Hi-tech Industrial Park Hope Bio-technology Co., Ltd	HB8275	Used to prepare TSB media.
Spectrophotometer	Shanghai Yidian Analysis Instrument Co.,Ltd.	76713100010	Used for pellicle biofilm cristal violet quantifivation.
Sterile Water	Sinopharm Chemical Reagent Co.,Ltd.	SW150302	Used to wash the pellicle biofilm.
Sterilized Nitrile Gloves	Beijing Labgic Technology Co.,Ltd.	223016852LLZA	Used for basic experimental operations.
Template DNA	Sangon Biotech (Shanghai) Co.,Ltd.	N/A	Used for DNA amplification in qPCR.
Thiamine	Bioolook Scientific Research Special	2180020	Used to prepare MSgg media.
Tryptone	Thermo Fisher Scientific	LP0042B	Used to prepare TSB media.
Tryptophan	Bioolook Scientific Research Special	2190020	Used to prepare MSgg media.
TSB Medium	Guangdong Huankai Microbial Sci. & Tech. Co.,Ltd.	024048	Broad-spectrum bacterial medium.
TSB-Msgg Meidium	Nanjing Agricultural University	N/A	Mixed medium for pellicle biofilm culture with wider applicability.
ZnCl2	Nanjing Chemical Reagent Co.,Ltd	C0310520123	Used to prepare MSgg media.