Algal Exudates Promote Conjugation in Marine Roseobacters

Einat Segev, Yemima Duchin Rapp, Lilach Yuda, Dor Matsliyah, Ilya V. Kublanov
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Abstract

Horizontal gene transfer (HGT) is a pivotal mechanism driving bacterial evolution, conferring adaptability within dynamic marine ecosystems. Among HGT mechanisms, conjugation mediated by Type IV secretion systems (T4SSs) plays a central role in the ecological success of marine bacteria. However, the triggers initiating conjugation events in the marine environment are not well understood. Roseobacters, abundant marine bacteria commonly associated with algae, possess a multitude of plasmids encoding T4SSs. Many Roseobacters are heterotrophic bacteria that rely on algal secreted compounds for supporting bacterial growth. Algal compounds therefore attract bacteria and promote colonization, including attachment to algal cells. Bacterial proximity, cell-to-cell contact, and attachment, can all foster HGT. Hence, we hypothesized that algal exudates, acting as chemoattractants for bacteria, may function as cues promoting bacterial HGT. Examination of various Roseobacters demonstrated that the genomic location of the T4SS impacts its functionality; a bacterial strain harboring a chromosomal-encoded T4SS does not perform conjugation, while a strain of the same species carrying a plasmid-encoded T4SS exhibits functional conjugation capability. Subsequently, we probed the influence of algal exudates on bacterial conjugation dynamics. Our findings revealed that algal exudates enhance plasmid transfer through conjugation but do not modulate the transcription of the conjugative machinery genes. These observations suggest that the bacterial responses to algal hosts evolved to correlate with an increased likelihood of encountering compatible partners for successful conjugation. Furthermore, since specific algae attract distinct bacterial populations, algae influence potential partners for genetic exchange and may shape the trajectory of bacterial evolution in the marine environment.
藻类分泌物促进海洋玫瑰杆菌的结合
水平基因转移(HGT)是驱动细菌进化的关键机制,赋予细菌在动态海洋生态系统中的适应性。在HGT机制中,IV型分泌系统(t4ss)介导的偶联在海洋细菌的生态成功中起着核心作用。然而,海洋环境中偶联事件的触发机制尚不清楚。玫瑰杆菌是一种丰富的海洋细菌,通常与藻类有关,具有大量编码t4ss的质粒。许多玫瑰杆菌是异养细菌,依靠藻类分泌的化合物来支持细菌生长。藻类化合物因此吸引细菌并促进定植,包括附着在藻类细胞上。细菌的接近,细胞间的接触和附着,都可以促进HGT。因此,我们假设藻类分泌物作为细菌的化学引诱剂,可能作为促进细菌HGT的线索。对各种玫瑰杆菌的检测表明,T4SS的基因组位置影响其功能;携带染色体编码的T4SS的菌株不进行偶联,而携带质粒编码的T4SS的菌株表现出功能性偶联能力。随后,我们探讨了藻类分泌物对细菌偶联动力学的影响。我们的研究结果表明,藻类渗出液通过偶联增强质粒转移,但不调节偶联机制基因的转录。这些观察结果表明,细菌对藻类宿主的反应与成功结合的可能性增加有关。此外,由于特定的藻类吸引不同的细菌种群,藻类影响了基因交换的潜在伙伴,并可能塑造海洋环境中细菌进化的轨迹。
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