The highly invasive field bindweed (Convolvulus arvensis), native to Europe and Asia, competes with crops, reduces yields, and acts as a reservoir for plant pathogens, increasing the potential for disease spread in agricultural systems (Sosnoskie et al. 2020; Wenninger et al. 2019). In July 2023, bindweed plants exhibiting little leaf, leaf discoloration, thickening, and overall stunted growth were observed in a 0.3 ha green cherry orchard in Kharja, Bani Kenanah, Irbid Governorate, Jordan (32°37'37.883"N, 35°52'49.185"E) (Fig. 1). Twenty out of 35 plants displayed symptoms, resulting in a 57% incidence rate. Since the symptoms resembled those associated with phytoplasma infections and bindweed's known role as a phytoplasma host (Jovic et al. 2021), DNA was extracted from six symptomatic plants and two healthy controls using the Qiagen DNeasy Plant Mini Kit, and PCR assay was conducted with the primer pair P1A/16S-SR to amplify near full-length phytoplasma 16S rDNA (about 1.5 kb) as described by Lee et al. (2004). All healthy controls tested negative, while all symptomatic plants tested positive. Amplicons were cloned into the pCRII-TOPO vector, sequenced, and a representative sequence was deposited in GenBank (Accession number PQ497569). Using iPhyClassifier (Zhao et al. 2009), the strain was identified as a 'Candidatus Phytoplasma omanense' (GenBank accession: EF666051, 16SrXXIX-A)-related strain, with 98.95% sequence identity, belonging to the 16SrXXIX group. The similarity coefficients were 0.93 and 0.97 compared to reference strains 16SrXXIX-A (EF666051) and 16SrXXIX-B (OL873126, Abu Alloush et al. 2023a), respectively. The phylogenetic analysis indicated that the newly detected field bindweed little leaf phytoplasma strain (designated FBLL1) is genetically distinct from these known subgroups and represents a novel subgroup, 16SrXXIX-C (Fig. 2). Further characterization of the FBLL1 strains was performed by PCR amplification of the rp (1.9 kb) and secY (1.3 kb) gene segments using specially designed primers: FBRP-F2/FBRP-R4 (5’-TTGGCCGCCTTCAAATCCTA-3’/5’-TCGGAGGAGAAGTTTTGGCT-3') for rp, and FBSecYF1/FBSecR1 (5’-CTTCTTTTGGTGATATCCCA-3’/5’-TGGCGGAAGTATTGAGATAAGAA-3') for secY. The resulting rp and secY gene sequences were deposited in GenBank (Accession numbers PQ505136 and PQ505137). BLASTN analysis revealed that the rp gene's top hit was 'Ca. P. pruni' (CP119306) with 75.60% identity, while the secY gene's top hit was 'Ca. P. phoenicium' (MN076652), with 73.47% identity. Compared to the 16S rRNA gene, the lower percent identity is due to the limited availability of 16SrXXIX rp and secY gene sequences for comparison. Field bindweed hosts several phytoplasmas, such as ‘Ca. P. solani’ (16SrXII-A), which is linked to Bois noir (BN) in grapevines, and ‘Ca. P. convolvuli’ (16SrXII-H), associated with bindweed yellows (Jovic et al. 2021; Abu Alloush et al. 2023b). ‘Ca. P. omanense’ has also been documented in bindweed in Lebanon (Fossaic et al. 2019) and Iran (Esmailzadeh Hosseini et al. 2016). As a confirmed reservoir of the BN phytoplasma, bindweed supports the pathogen’s persistence and vector-mediated transmission to grapevines (Jovic et al. 2021). This report marks the first identification of ‘Ca. P. omanense’-related strains (16SrXXIX-C, novel subgroup) in bindweed in Jordan. These findings suggest that bindweed may serve as a potential reservoir for a broader range of phytoplasmas than previously recognized, with a wider geographical distribution. Its invasive growth near crops, such as grapevines, raises concerns about the potential phytoplasma spillover. This highlights the need for improved monitoring and management, which includes targeted herbicide application, mechanical removal, and biological control to protect agricultural biosecurity.