Brief Communication

Broad range plastid genome editing with monomeric
TALE-linked cytosine and dual base editors
Xiaoyu Wang1,2, Tyson Fang3, Jason Lu1, Leena Tripathi4 and Yiping Qi1,5,*

1Department of Plant Science and Landscape Architecture, University of Maryland, College Park, Maryland, USA
2College of Life Science and Food Engineering, Inner Mongolia Minzu University, Tongliao, China
3University of Michigan, Ann Arbor, Michigan, USA
4International Institute of Tropical Agriculture (IITA), Nairobi, Kenya
5Institute for Bioscience and Biotechnology Research, University of Maryland, Rockville, Maryland, USA

Received 29 December 2023;

revised 19 March 2024;

accepted 3 April 2024.

*Correspondence (Tel 301 405 7682; fax 301 314 9308; email yiping@umd.

edu)

Keywords: monomeric TALE-linked base editors, cytosine base

editor, dual base editor, mTCBE, plastid, rice.

Editing of the plastid genome helps understand the molecular

functions of plastid genes and engineer desired traits in crops

(Maliga, 2022). The DddA-derived cytosine base editors (DdCBEs)

enable C-to-T editing in mitochondrial and plastid genomes (Kang

et al., 2021; Li et al., 2021; Mok et al., 2020; Nakazato

et al., 2021). Recently, Cho et al. (2022) developed TALE-linked

deaminases (TALED) that can catalyse A-to-G base conversions in

human mitochondria.

Harnessing the discovery of DddAtox (Cho et al., 2022), we

generated new monomeric TALE-linked CBEs for plastid editing

by exploring two cytidine deaminases: a human APOBEC3A

variant (hA3A-Y130F) with broad editing windows (Ren

et al., 2021) and an improved cytidine deaminase based on TadA

(Lam et al., 2023), generating mTCBE and mTCBE-T respectively.

Also, we explored a TadA-derived deaminase that can simulta-

neously deaminate cytosines and adenines (Lam et al., 2023)

towards engineering a dual base editor, named mTCABE-T. None

of these deaminases have been previously investigated for

organellar genome editing in either plants or humans.

We first assembled the left or right TALE arrays targeted to

three rice plastid genes encoding core components of photosys-

tem II (OsPsbA), photosystem I (OsPsaA), and RNA component of

the 30S ribosome subunit (Os16SrRNA). The three monomeric

plastid base editors, along with DdCBE and Split-TALED controls,

were constructed for expression in rice (Figure 1a). We evaluated

base editing efficiency in regenerated rice calli through targeted

amplicon deep sequencing. Impressively, mTCBE induced high-

efficiency C-to-T conversions, with average editing frequencies of

42.3%, 21.6%, and 19.4% at OsPsbA, OsPsaA, and Os16SrRNA

respectively (Figure 1b–d). DdCBE catalysed C-to-T conversions

with average editing efficiencies of 7.8%, 33.5% and 34.2% at

these target sites (Figure 1b–d). By contrast, mTCBE-T was less

efficient than mTCBE, displaying C-to-T editing efficiencies of

only 5.8%, 3.3%, and 0.8% in these targets (Figure 1b–d).
Overall, mTCBE appears to be a robust base editor alongside

DdCBE (Figure 1e).

Remarkably, mTCABE-T exhibited C-to-T substitutions with

average efficiencies of 33.2%, 21.3%, and 5.0% as well as

A-to-G substitutions with average efficiencies of 17.5%, 7.2%,

and 7.8%. The Split-TALED induced C-to-T editing with average

efficiencies of 2.7%, 15.0%, and 8.9% as well as A-to-G editing

with average efficiencies of 12.9%, 4.8%, and 3.3% in the same

targets (Figure 1b–d), consistent with Mok et al. (2022) report,

which noted that UGI-free split can induce C-to-T and A-to-G

edits. mTCABE-T is a better dual base editor with higher C-to-T

and A-to-G editing efficiencies than Split-TALED (Figure 1e,f).

Further sequence analysis confirmed frequent simultaneous

C-to-T and A-to-G editing by six mTCABE-T editors at the three

target loci (Figure 1g, Figure S1).

We further examined plastid base editing profiles by different

editors. As expected, DdCBE favoured editing cytosines of a 50-TC
context within spacer regions (Figure 1h, Figure S2). Notably,

mTCBE often generated distinct editing patterns and efficiently

converted cytosines in a 50-TCC, AC, and GC context at the

OsPsbA target (Figure 1h). Similarly, at OsPsaA, mTCBE converted

cytosines in TC and TCC context (Figure S2). At Os16SrRNA, four

cytosines were converted to T (Figure S2). Although editing

frequently happened in the spacer regions, both mTCBE and

mTCABE-T also showed base editing at positions upstream or

downstream of the spacer region, resulting in only partly

overlapping editing profiles by the left and right TALEs

(Figure 1h,i, Figure S2). Our data suggest that these monomeric

base editors have broader editing ranges than DdCBEs.

We next investigated these monomeric TALE-linked base

editors (mTBEs) in T0 transgenic plants. At OsPsbA, targeted

deep sequencing revealed that C-to-T base editing occurred at

multiple positions, with editing frequencies reaching up to 81%

and 86% based on 16 and 26 T0 plants by mTCBE and mTCABE-T

respectively (Figure 1j). Significantly, such high-frequency tar-

geted mutagenesis by mTCBE and mTCABE-T translated to a

loss-of-function albino phenotype (Figure 1k). Hence, we

genetically confirmed the role of OsPsbA in photosynthesis in

rice. Consistent with the calli data, mTCBE-T exhibited much

lower efficiency, and none of the 29 T0 seedlings plants showed

an albino phenotype (Figure 1k). Our data suggest that high-

efficiency editing of plastid genome copies at multiple editable

Please cite this article as: Wang, X., Fang, T., Lu, J., Tripathi, L. and Qi, Y. (2024) Broad range plastid genome editing with monomeric TALE-linked cytosine and dual

base editors. Plant Biotechnol. J., https://doi.org/10.1111/pbi.14358.

ª 2024 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd.
This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and
distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

1

Plant Biotechnology Journal (2024), pp. 1–3 doi: 10.1111/pbi.14358

https://orcid.org/0000-0001-5723-4981
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https://orcid.org/0000-0001-5723-4981
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https://orcid.org/0000-0002-9556-6706
https://orcid.org/0000-0002-9556-6706
mailto:yiping@umd.edu
mailto:yiping@umd.edu
https://doi.org/10.1111/pbi.14358
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Figure 1 Monomeric TALE-linked cytosine and dual base editors for plant plastid genome editing. (a) Schematic of five TALE-based plastid base editors

driven by the dual RNA polymerase II promoter. (b–d) The five base editors in regenerated rice calli were assessed at OsPsbA, OsPsaA, and Os16SrRNA. Error

bar represents mean � standard deviation (SD) of 8–20 independent calli. (e–f) Editing efficiency comparison of five base editors across these three target

sites. (g) Editing efficiencies and patterns of mTCABE-T at OsPsbA. A-to-G and C-to-T base edits are shown in red and blue. (h, i) The heat map illustrates

frequencies of C-to-T and A-to-G substitutions at OsPsbA. The colour gradations on the heat map are derived from data gathered from 8 to 20

independent calli. Left and right TALE binding sites are depicted as blue and red rectangles, denoted by ‘L’ and ‘R’ respectively. (j) Assessment of L-mTCBE,

L-mTCABE-T, and L-mTCBE-T in transgenic rice plants at OsPsbA. The value is generated from 16 to 29 transgenic rice seedlings. T0 lines with lower than

10% C-to-T mutation frequency were considered unedited. (k) The phenotype of five representative transgenic lines generated from L-mTCBE,

L-mTCABE-T, and L-mTCBE-T base editors. Bar = 5 cm. L, line. (l) Heat map showing C-to-T conversions at OsPsbA site from five representative transgenic

lines by different base editors. Different letters indicate significant differences (P < 0.05; one-way ANOVA, Tukey’s test) in (e), and (j).

ª 2024 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd., 1–3

Xiaoyu Wang et al.2

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positions could effectively knockout gene function (Figure 1l,

Figure S3). Sanger sequencing showed consistent mutation types

in different leaves of each edited plant, including homoplasmic

edits, which suggests high probability of germ-line transmittable

inheritance (Figure S4). At Os16SrRNA, C-to-T editing efficiency

of up to 80% was also observed in T0 plants with mTCBE and

mTCABE-T (Figure S5). Together, our data demonstrates mTCBE

and mTCABE-T are potent plastid base editors in transgenic rice

plants.

We analysed off-target activity of mTCBE and mTCABE-T at the

OsPsbA site. Off-target mutations were induced at two of

the four top candidate sites, only in few edited lines (Figure S6).

Thus, sequences of TALE binding sites and expression of the

editors can both affect the off-target editing outcomes.

In summary, we demonstrated two novel mTBEs, mTCBE, and

mTCABE-T, for efficient plastid genome editing in rice. These

mTBEs offer several advantages over DdCBEs. First, use of single

TALE protein streamlines the vector construction process. Second,

these mTBEs have broad editing windows. Third, mTCABE-T is an

efficient dual base editor. Since mTCABE-T edits both strands of

DNA, it can simultaneously induce four different types of base

conversions on a single strand such as a coding sequence: C-to-T,

A-to-G, T-to-C, and G-to-A. Thus, mTCABE-T in theory could

potentially edit every base within its editing window. Hence,

mTCABE-T would be a powerful high-density-targeted mutagen-

esis tool for protein evolution. Although we only demonstrated

mTCABE-T in plastids, it is anticipated that mTCABE-T, when

equipped with mitochondrial localization signals, could enable

base editing in mitochondria in plants and beyond.

Acknowledgements

This work was supported by MAES (MD-PSLA-243089), NSF

(IOS-2029889 and IOS-2132693), and USAID (22010332).

Conflict of interest

The authors declare no competing financial interests.

Author contributions

Y.Q. and X.W. designed the study. X.W., T.F., and J.L. conducted

experiments. X.W. and Y.Q. analysed the data. Y.Q., X.W., and

L.T. wrote the article with input from all authors.

Data availability statement

The data that supports the findings of this study are available in

the supplementary material of this article.

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Supporting information

Additional supporting information may be found online in the

Supporting Information section at the end of the article.

Figure S1 Editing efficiencies and patterns induced by mTCABE-T

in Os16SrRNA (A) and OsPsaA (B).

Figure S2 Heatmaps showing the frequencies of C-to-T and

A-to-G substitutions across different positions targeted to OsPsaA

(A, B), and Os16SrRNA (C, D).

Figure S3 Heatmap showing A-to-G conversions at OsPsbA from

five representative transgenic lines generated from indicated base

editors separately.

Figure S4 Representative genotypes of mTCBE (A) and

mTCABE-T (B) induced edits in five randomly selected leaves

of T0 plants.

Figure S5 Evaluation of L-mTCBE, L-mTCABE-T, and L-mTCBE-T

in transgenic rice plants at the Os16SrRNA site.

Figure S6 Analysis of off-target mutations induced by mTCBE

and mTCABE-T in transgenic T0 lines.

Table S1 PCR primers used in this study.

ª 2024 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd., 1–3

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