Mesorhizobium salmacidum sp. nov. and Mesorhizobium argentiipisi sp. nov. are symbionts of the dry-land forage legumes Lessertia diffusa and Calobota sericea

Muema, Esther K.; Van Lill, Melandre; Venter, S.N. (Stephanus Nicolaas); Chan, Wai Yin; Claassens, Ricu; Steenkamp, Emma Theodora

Mesorhizobium salmacidum sp. nov. and Mesorhizobium argentiipisi sp. nov. are symbionts of the dry-land forage legumes Lessertia diffusa and Calobota sericea

dc.contributor.author	Muema, Esther K.
dc.contributor.author	Van Lill, Melandre
dc.contributor.author	Venter, S.N. (Stephanus Nicolaas)
dc.contributor.author	Chan, Wai Yin
dc.contributor.author	Claassens, Ricu
dc.contributor.author	Steenkamp, Emma Theodora
dc.date.accessioned	2025-06-06T06:31:47Z
dc.date.available	2025-06-06T06:31:47Z
dc.date.issued	2025-03
dc.description	DATA AVAILABILITY : All data generated or analysed from this study are included in this published article. For example, the whole genome sequences of the five representative isolates used in this study have been deposited in the NCBI database with accession numbers: GCA_037179605.1 (Ld1326N3Ts), GCA_037179655.1 (Cs1299R1N1), GCA_037179625.1 (Cs1299R1N3), GCA_037179725.1 (Cs1321R2N1), and GCA_037179585.1 (Cs1330R2N1Ts). Their corresponding raw sequence data were also submitted to NCBI’s Sequence Read Archive (SRA) under the BioProject accession number PRJNA1028499. The sequences for all PCR products were deposited into the NCBI database under accession numbers OQ458741-OQ458755 for 16S rRNA, with links to BioProject accession numbers PRJNA937154 for atpD, PRJNA937057 for recA, PRJNA938292 for dnaK, PRJNA938296 for glnII, PRJNA938285 for rpoB, and PRJNA940066 for nifH. Any additional data are provided as supplementary information files.
dc.description	SUPPLEMENTARY FIGURE S1. Maximum likelihood phylogeny based on 16S rRNA gene sequences data for the fifteen isolates investigated reference and outgroup strains sequences. Strains indicated in blue and green colors represent those investigated in this study. The DNA sequences for Bradyrhizobium japonicum USDA6T and Bradyrhizobium canariense BTA-1T were used for outgroup purposes, while the rest of the Mesorhizobium strains sequences were used as reference sequences. The accession numbers for the sequences are indicated in brackets. Type strains or sequences are indicated as T or Ts. Bootstrap values were inferred using 1000 pseudo replicates with only those values >50% indicated at the nodes. The scale bar indicates the number of nucleotide changes per site.
dc.description	SUPPLEMENTARY FIGURE S2. Maximum-likelihood phylogenies of atpD, glnII, dnaK, recA and rpoB house-keeping genes for the fifteen isolates being investigated, reference and outgroup strains sequences. Strains highlighted in blue and green colours represent Lineages I and II respectively representing those investigated in this study. Sequences of Bradyrhizobium japonicum USDA6T and Bradyrhizobium canariense BTA-1T were used for outgroup purposes. Type strains or sequences are indicated as T or Ts and those strains whose names are not validly published according to LPSN are indicated with inverted commas. Bootstrap support values were inferred from 1000 pseudoreplicates and only values greater than 50% are indicated at the nodes. The scale bar indicates nucleotide substitutions per site. GenBank accession numbers are listed in (Supplementary Table S1).
dc.description	SUPPLEMENTARY FIGURE S3. UBCG phylogenomic tree of all our five isolates and representative strains of described and undescribed Mesorhizobium sensu stricto in the GTDB with genome accession numbers indicated in brackets. Strains highlighted in blue and green colours represent Lineages I and II respectively representing those investigated in this study with the proposed type sequences of novel species indicated in bold. Type strains or sequences are indicated as T or Ts and those strains whose names are not validly published according to LPSN are indicated with inverted commas. Bootstrap support values were inferred from 1000 pseudoreplicates and only values greater than 80% are indicated at the nodes, bifurcations with bootstrap support of 100% are indicated as circles on the particular branch. Gene support index (GSI) values ‘n’ (highlighted in red in the tree) demonstrate how many of the bacterial core genes support that bifurcation. Only values lower than the maximum value are demonstrated next to bootstrap values (i.e., < 92). USDA 6T was used as the outgroup. The scale bar indicates nucleotide substitutions per site.
dc.description	SUPPLEMENTARY FIGURE S4. Maximum-likelihood phylogenetic tree constructed using nifH gene sequences of the strains investigated in this study, reference, and outgroup strains sequences. Strains highlighted in blue and green colours represent those investigated in this study. Sequences of Bradyrhizobium japonicum USDA6T was used for outgroup purposes. Type strains or sequences are indicated as (T or Ts). Bootstrap support values were inferred from 1000 pseudoreplicates and only values greater than 50% are indicated at the nodes. The scale bar indicate nucleotide substitutions per site. The accession numbers for the sequences are indicated in Supplementary Table S5.
dc.description	SUPPLEMENTARY FIGURE S5. Maximum-likelihood phylogenetic tree constructed using nodC gene sequences of the strains investigated in this study, reference, and outgroup strains sequences. Strains indicated in blue and purple colours represent those investigated in this study. Sequences of Bradyrhizobium japonicum USDA6T and Bradyrhizobium canariense CCBAU 51257 were used for outgroup purposes. Type strains or sequences are indicated as T or Ts. Bootstrap support values were inferred from 1000 pseudo replicates and only values greater than 50% are indicated at the nodes. The scale bar indicates nucleotide substitutions per site. The accession numbers for the sequences are indicated in Supplementary Table S6.
dc.description	SUPPLEMENTARY FIGURE S6. Maximum-likelihood phylogenetic tree constructed using nodA gene sequences of the strains investigated in this study, reference, and outgroup strains sequences. Strains highlighted in blue and green colours represent those investigated in this study. Sequences of Bradyrhizobium japonicum USDA6T and Bradyrhizobium canariense BTA-1T were used for outgroup purposes. Type strains sequences are indicated as T or Ts. Bootstrap support values were inferred from 1000 pseudo replicates and only values greater than 50% are indicated at the nodes. The scale bar indicates nucleotide substitutions per site. The accession numbers for the sequences are indicated in Supplementary Table S7.
dc.description	SUPPLEMENTARY FIGURE S7. Maximum-likelihood phylogenetic tree constructed using nifH gene sequences of the strains investigated in this study, nifH metabarcoding sequences of operational taxonomic units (OTUs), reference strains, and outgroup strains sequences. Strains indicated in blue and purple colours represent those investigated in this study. Sequences of Bradyrhizobium japonicum USDA6T and Bradyrhizobium diazoefficiens USDA110T were used for outgroup purposes. The isolates marked in bold are sequences of OTUs from the legume rhizosphere soils, with legume species hosts indicated in square brackets, followed the by locations of rhizosphere soils and seeds sampling. The accession numbers for the sequences are indicated in brackets. Type strains are indicated as T or Ts. Bootstrap support values were inferred from 1000 pseudo replicates and only values greater than 50% are indicated at the nodes. The scalebars indicates nucleotide substitutions per site.
dc.description	SUPPLEMENTARY TABLES
dc.description.abstract	Legumes Lessertia diffusa and Calobota sericea, indigenous to South Africa, are commonly used as fodder crops with potential for sustainable livestock pasture production. Rhizobia were isolated from their root nodules grown in their respective soils from the Succulent Karoo biome (SKB) in South Africa, identified and characterized using a polyphasic approach. Sequence analysis of the 16S rRNA gene confirmed all isolates as Mesorhizobium members, which were categorized into two distinct lineages using five housekeeping protein-coding genes. Lineage I included 14 strains from both legumes, while Lineage II comprised a single isolate from C. sericea. Differences in phenotypic traits were observed between the lineages and corroborated by average nucleotide identity analyses. While all strains nodulated their original hosts, strains from C. sericea failed to effectively nodulate L. diffusa and vice versa. Phylogenetic analyses of nitrogen fixation (nifH) and nodulation (nodA, nodC) loci grouped all strains in a single clade, suggesting that unique symbiotic loci determine nodulation of these legumes. We designated Lineage I and II as Mesorhizobium salmacidum sp. nov. (Ld1326Ts; GCA_037179605.1Ts) and Mesorhizobium argentiipisi sp. nov. (Cs1330R2N1Ts; GCA_037179585.1Ts), using genome sequences as nomenclatural types according to the Nomenclatural Code for Prokaryotes using Sequence Data, thus avoiding complications with South Africa's biodiversity regulations. Identifying effective microsymbionts of L. diffusa and C. sericea is essential for conservation of Succulent Karoo Biome, where indigenous invasive species like Vachellia karroo and non-native Australian acacia species are present. Furthermore, targeted management practices using effective symbionts of the studied legumes can sustain the biome's socio-economic contribution through fodder provision.
dc.description.department	Biochemistry, Genetics and Microbiology (BGM)
dc.description.department	Forestry and Agricultural Biotechnology Institute (FABI)
dc.description.librarian	hj2025
dc.description.sdg	SDG-02: Zero Hunger
dc.description.sdg	SDG-15: Life on land
dc.description.sponsorship	Open access funding provided by Stellenbosch University.
dc.description.uri	https://link.springer.com/journal/10482
dc.identifier.citation	Muema, E.K., van Lill, M., Venter, S.N. et al. Mesorhizobium salmacidum sp. nov. and Mesorhizobium argentiipisi sp. nov. are symbionts of the dry-land forage legumes Lessertia diffusa and Calobota sericea. Antonie van Leeuwenhoek 118, 54 (2025). https://doi.org/10.1007/s10482-025-02063-2.
dc.identifier.issn	0003-6072 (print)
dc.identifier.issn	1572-9699 (online)
dc.identifier.other	10.1007/s10482-025-02063-2
dc.identifier.uri	http://hdl.handle.net/2263/102711
dc.language.iso	en
dc.publisher	Springer
dc.rights	© The Author(s) 2025. Open Access This article is licensed under a Creative Commons Attribution 4.0 International License
dc.subject	Legumes
dc.subject	Lessertia diffusa
dc.subject	Calobota sericea
dc.subject	Succulent Karoo biome (SKB)
dc.subject	South Africa (SA)
dc.subject	Sustainable livestock pasture production
dc.subject	Multilocus sequence analysis (MLSA)
dc.subject	Nodulation
dc.subject	Rhizosphere soils
dc.subject	Symbiotic loci
dc.subject	Up-to-date bacteria core gene
dc.title	Mesorhizobium salmacidum sp. nov. and Mesorhizobium argentiipisi sp. nov. are symbionts of the dry-land forage legumes Lessertia diffusa and Calobota sericea
dc.type	Article