Construction
of protocells with hierarchical structures and living
functions is still a great challenge. Growing evidence demonstrates
that the membraneless organelles, which facilitate many essential
cellular processes, are formed by RNA, protein, and other biopolymers
via liquid–liquid phase separation (LLPS). The formation of
the protocell in the early days of Earth could follow the same principle.
In this work, we develop a novel coacervate-based protocell containing
membraneless subcompartments via spontaneous liquid–liquid
phase separation by simply mixing single-stranded oligonucleotides
(ss-oligo), quaternized dextran (Q-dextran), and poly(l-lysine)
(PLL) together. The resulting biphasic droplet, with PLL/ss-oligo
phase being the internal subcompartments and Q-dextran/ss-oligo phase
as the surrounding medium, is capable of sequestering and partitioning
biomolecules into distinct regions. When the droplet is exposed to
salt or Dextranase, the surrounding Q-dextran/ss-oligo phase will
be gradually dissociated, resulting in the chaotic movement and fusion
of internal subcompartments. Besides, the external electric field
at a lower strength can drive the biphasic droplet to undergo a deviated
circulation concomitant with the fusion of localized subcompartments,
while a high-strength electric field can polarize the whole droplet,
resulting in the release of daughter droplets in a controllable manner.
Our study highlights that liquid–liquid phase separation of
biopolymers is a powerful strategy to construct hierarchically structured
protocells resembling the morphology and functions of living cells
and provides a step toward a better understanding of the transition
mechanism from nonliving to living matter under prebiotic conditions.