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Differential Cytotoxicity, Cellular Uptake, Apoptosis and Inhibition of BRCA1 Expression of BRCA1-Defective and Sporadic Breast Cancer Cells Induced by an Anticancer Ruthenium(II)-Arene Compound, RAPTA-EA1.
International Journal of Nanomedicine
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International Journal of Nanomedicine downloaded from https://www.dovepress.com/ on 04-Feb-2022
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Nanotechnology-Employed Bacteria-Based
Delivery Strategy for Enhanced Anticancer Therapy
Zixuan Ye 1, *
Lizhen Liang 1, *
Huazhen Lu 1
Yan Shen 2
Wenwu Zhou 3
Yanan Li 1
1
School of Food Science and
Pharmaceutical Engineering, Nanjing
Normal University, Nanjing, People’s
Republic of China; 2State Key Laboratory of
Natural Medicines, Center for Research
Development and Evaluation of
Pharmaceutical Excipients and Generic
Drugs, Department of Pharmaceutics,
School of Pharmacy, China Pharmaceutical
University, Nanjing, People’s Republic of
China; 3National Experimental Teaching
Demonstration Center of Pharmacy,
School of Pharmacy, China Pharmaceutical
University, Nanjing, People’s Republic of
China
*These authors contributed equally to this
work
Correspondence: Yanan Li
School of Food Science and
Pharmaceutical Engineering, Nanjing
Normal University, Nanjing, People’s
Republic of China
Tel +8615051850598
Email liyanan@njnu.edu.cn
Wenwu Zhou
National Experimental Teaching
Demonstration Center of Pharmacy,
School of Pharmacy, China
Pharmaceutical University, Nanjing,
People’s Republic of China
Email dancingzww@163.com
Abstract: Bacteria and their derivatives (membrane vesicles, MVs) exhibit great advantages
for targeting hypoxic tumor cores, strong penetration ability and activating immune
responses, holding great potential as auspicious candidates for therapeutic and drugdelivery applications. However, the safety issues and low therapeutic efficiency by single
administration still need to be solved. To further optimize their performance and to utilize
their natural abilities, scientists have strived to modify bacteria with new moieties on their
surface while preserving their advantages. The aim of this review is to give a comprehensive
overview of a non-genetic engineering modification strategy that can be used to optimize the
bacteria with nanomaterials and the design strategy that can be used to optimize MVs for
better targeted therapy. Here, the advantages and disadvantages of these processes and their
applicability for the development of bacteria-related delivery system as antitumor therapeutic
agents are discussed. The prospect and the challenges of the above targeted delivery system
are also proposed.
Keywords: bacteria, nanomaterial, targeted delivery, immune response, membrane vesicles
Introduction
Due to the abnormal hyperplasia of the vascular system in tumor tissue, a specific
anaerobic, acidic microenvironment is formed in tumors. Over the past decades,
targeting delivery of therapeutic drugs into cancer with reduced side effects still
remains a challenge in cancer therapy. Researchers have made a series of attempts
in the drug delivery systems; various viral vectors (e.g., adenovirus, adenoassociated virus), abiotic carriers (e.g., micelles, liposomes, carbon materials,
inorganic structures, self-assembled peptide and protein nanostructures) and cell
carriers (e.g., bacteria, red blood cells) were developed to achieve active or passive
targeting to tumor tissue.1–4 Among the cell carriers, bacteria have been explored in
cancer therapy for more than a century, including Salmonella, Listeria monocyto
genes and Bifidobacterium. Compared with other synthetic carriers, bacteria exhibit
multiple advantages, such as (1) the unique ability to preferentially penetrate and
colonize anaerobic tumors by an aerotaxis or chemotaxis pathway;5 (2) their
intrinsic genetic system, which is easily engineered to deliver antitumor agents
such as genes or proteins;6 and (3) their own immune-stimulating activity,7 which
allows them to act as adjuvants in tumor immunotherapy. Despite the above
advantages, several challenges in bacteria-mediated delivery still exist, such as
(1) the risks and safety of bacteria and their derivatives;8–10 (2) the active targeting
efficiency remains to be enhanced; and (3) expanding the types of drug carried by
International Journal of Nanomedicine 2021:16 8069–8086
Received: 16 July 2021
Accepted: 29 October 2021
Published: 14 December 2021
8069
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Ye et al
bacteria.11 To address these concerns, a nanotechnologyemployed bacteria-based delivery strategy is considered to
be an effective strategy to improve bacteria-mediated
tumor therapy. In this review, the current developments
and their deficiencies of bacteria as therapeutic agents or
delivery system are first introduced. Then, we focus on the
design strategy of a nanotechnology-employed bacteriabased drug delivery system (e.g., bacteria-derived nanohybrid, bacteria-derived outer membrane vesicles based
nano-platforms) and highlight the interaction between bac
teria and nanomaterials and the modification strategies to
complement or enhance their therapeutic applicability in
cancer field. This review can provide more perspectives
for
the
practical
medicinal
application
for
a nanotechnology-employed bacteria-based drug delivery
system in the future.
Bacteria Used as Carriers in
Anticancer Therapeutics
In the design of a bacteria-based drug-delivery system, the
most important thing is the selection of a bacterial strain
with specific characteristics to target the tumor area. Until
now, various bacterial strains have been used to combat
tumors, including Escherichia coli, Clostridium, Listeria
monocytogenes, Serratia marcescens, magnetotactic bac
teria (MTB) and Salmonella typhimurium.12 It is noted that
the above bacteria are mainly divided into two types
according to application. One is that pathogenic or attenu
ated bacteria themselves act as therapeutic agents alone,
relying on the strong immune stimulation. The other is
attenuated or non-pathogenic bacteria mainly acting as
a carrier to assist other antitumor therapy.
In 1891, W Busch surprisingly found significant tumor
reduction after infection of Streptococcus pyogenes in
sarcoma patients. Inspired by this phenomenon, physician
W. B. Coley firstly purified and prepared mixed bacteria
vaccine
(inactivated
Serratia
marcescens
and
Streptococcus pyogenes), which has treated thousands of
patients with various tumors and mostly exhibited effec
tive tumor suppression. Therefore, attributed to physiolo
gical colonization differences between normal and
neoplastic tissues, the pathogenic anaerobes were initially
developed as immune-stimulating vaccines. The unu
sually successful case is Mycobacterium bovis BCG,
which had been clinically used in postsurgical bladder
cancer to prevent cancer recurrence via intravesical infu
sions of M. bovis BCG suspension.13–15 The clinical data
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indicate that bladder cancer recurrence rate decreased
significantly after administration of BCG vaccines.15,16
However, the immune response of most bacteria-based
vaccines is not long-lasting, and is usually accompanied
with poor selectivity and serious side-effects. Gradually,
the genetically modified and attenuated pathogenic bac
teria were developed for safer and longer application
(Table 1). Firstly, the attenuated bacteria-based vaccines
were carried out by deleting the disease-causing genes to
reduce risks, including Aduro’s Listeria monocytogenesbased platform, Salmonella typhimurium,17,18 etc. Then,
the attenuated bacteria were engineered to express mole
cules, or antigens to specifically enhance the immune
antitumor responses. In preclinical study, C. novyi-NT19
induced a strong inflammatory response involving proinflammatory cytokines such as Interleukin-6, granulo
cyte colony-stimulating factor (G-CSF), macrophage
Inflammatory Protein-2, and tissue inhibitor of metallo
proteinases 1(TIMP-1) that recruit a substantial amount of
immune cells to tumor site to generate a durable adaptive
anti-tumor immunity.20,21 In clinic, S. typhimurium was
modified to express interleukin-2 (IL-2), which showed
no toxicity or adverse events. However, there was no
evidence of complete response and survival advantage in
the single dose clinical Phase I study.22 A Listeria-based
vaccine vector takes advantage of the intrinsic capacity of
the bacterium to forcefully invade antigen-presenting
cells (APCs) and engineering expression of shared tumorassociated antigens or unique neoepitopes personalized to
each patient.23–26 Live attenuated, double-deleted
(LADD) Listeria monocytogenes encoded the human
mesothelin as a tumor-associated antigen overexpressed
in 30–70% of non-small cell lung cancer (JNJ-757) indi
cated well tolerated safety in the clinical phase I study. It
is noted that the JNJ-757 as monotherapy only induced
limited adaptive immune response. Even combined with
nivolumab, the clinical best overall disease response with
the combination was stable disease in four of 12 patients,
which led to not proceeding to Phase 2.27 In addition to
the above pathogenic bacteria or attenuated pathogenic
bacteria, some non-pathogenic bacteria or probiotics
including Bifidobacterium, Lactobacillus, and E. coli
Nissle 1917 were also applied in antitumor investigation.
However, from the preclinical and clinical results, all the
pathogenic bacteria or attenuated pathogenic bacteria
after genetic modification only induced insufficient
tumor suppression, which could not completely kill
tumors. Among these non-pathogenic bacteria, the
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Table 1 Clinical Trials of Bacterial Tumor Therapy (https://www.clinicaltrials.gov/)
Bacteria
NCT
Phase
Modification
Route/Tumor Types
Number
Mycobacterium bovis
Market
None
Intravesical infusions/bladder
cancer
Salmonella typhimurium
NCT01099631
Phase 1
Knock out msbb, puri, and expressed IL-2
Oral administration/Unresectable
hepatic metastasis
Salmonella typhimurium
NCT00004988
Phase 1
Knock out msbb, puri
(VNP20009)
Clostridium butyricum CBM
solid tumors
NCT03922035
588
Clostridium novyi-NT
Intravenous injection/Advanced
Phase 1,
None
Given PO/Hematopoietic and
Recruiting
NCT01924689
Phase 1
Lymphoid Cell Neoplasm
Eliminate a residential phage carrying α-toxin
Intratumoral Injection/Solid
tumor malignancies
Double-Deleted Listeria
NCT02625857
Phase 1
Monocytogenes (pLADD) JNJ64041809
E. coli Nissle 1917
Drug: SYNB1891
NCT04167137
Drug: Atezolizumab
Phase 1,
Recruiting
Delete of two virulence genes from the
Intravenous administration/
L. monocytogenes chromosome—actin
assembly protein
Metastatic castration-resistant
prostate cancer
Encode diadenylate cyclase, dihydropyridine
dicarboxylate synthase and thymidylate
Intratumoral injection/Metastatic
solid tumors and lymphoma
synthetase
engineered E. coli Nissle 1917 (SYNB19891) was first to
proceed to Phase 1. Different from other engineered bac
teria, SYNB1891 expressed cyclic di-nucleotidesproducing enzymes (diadenylate cyclase) under
a tetracycline-inducible promoter (Ptet) which could acti
vate the stimulator of interferon genes (STING) pathway
locally in tumor, suggesting a potentially advantageous
safety profile and significantly broader set of tools for
genetic manipulation.28
While the clinical studies of various bacteria or their
spores demonstrated that the treatment resulted in reliable
colonization in anaerobic tumor tissue, complete suppres
sion of tumor, including its well-oxygenated regions
inhospitable to anaerobic bacteria, was still a challenge.
Recently, the synergistic combination therapy with bac
teria were carried out in clinic to kill tumor cells in both
well-oxygenated and hypoxic regions, including che
motherapeutic drugs, immune drugs (NCT03371381).
Several clinical data of these combination therapies indi
cated increased oncolysis and enhanced anti-tumor
response compared with the single bacteria therapy
(NCT04167137). Thus, the next phase of the development
of bacterial therapy involved methods to simultaneously
integrate various therapies onto the bacterial therapy, in
which the bacteria act as delivery vectors.
International Journal of Nanomedicine 2021:16
Bacteria-Nanoparticle Biohybrids
The biohybrid concept offers a means to broaden anti
tumor application of bacteria by integrating live bac
teria with abiotic systems such as micro/nanoparticles,
allowing them to work simultaneously to achieve
advanced levels of functionality beyond that achievable
by each component alone. As is known, when given
via a systemic injection such as i.v., some living organ
isms may face some challenges in that it rapidly caused
serious systemic inflammatory responses and experi
enced antibody-mediated clearance. Hence, the hybrid
by modifying nanomaterial on the surface of bacteria
provides a “shielding” strategy to overcome the sys
temic inflammation. Moreover, a biohybrid exploits the
navigation of targeting bacteria to deliver biomedical
cargo to tumor tissue, by assembling drug-loading car
gos around the motile bacteria. On the one hand, the
biohybrid could serve as a highly flexible chassis to
provide broader potential application in a variety of
therapeutic combinations, by precisely adjusting the
types of loading agents in the coating materials, such
as chemotherapeutic drugs, photothermal drugs, photo
dynamic drugs or immunotherapeutic drugs. Upon the
arrival at tumor sites, the smart release of cargos
locally inside the tumor would be achieved to
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guarantee maximum efficiency and reduced side
effects. Thus, the triggered drug release by the specific
tumor environment (including slightly acidic pH, spe
cific enzyme, ROS) could further facilitate the versatile
elaboration of these biohybrids.29 Herein, we focus on
the binding strategies between bacteria and drugloading coating material, their efficiency and scope of
application in the anticancer field (Figure 1).
Covalent Bond
Bacteria as a type of living organism, are convenient to be
chemically modified because of various chemical groups
on their surface, such as amino groups (–NH2) intrinsic to
bacteria cell membrane proteins. Some nanoparticles could
achieve covalently chemical conjugation by functionaliz
ing with the reactive groups (–COOH, -CHO), which
generated amide bond or imine bond to form bacteria-
Figure 1 The illustration of fabrication of bacteria-nanoparticle bio-hybrids via chemical bonds, physical adsorption, biomineralization and other binding forms. Covalent
bonds could be formed via reaction of groups on the surface of bacteria and nanoparticles; physical adsorption occurs between negative charged bacteria and positive
charged nanoparticles, which are always coated with cationic polymers such as chitosan and PEI; biomineralization is the process of grabbing and turning metal ions into the
element metal on the surface of bacteria; other binding forms include the bioaffinity or specific attachment such as biotin-streptavidin affinity and antigen-antibody binding.
Abbreviations: PEI, polyethylenimine; LPS, lipopolysaccharides; MOF, metal organic framework.
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nanomaterial biohybrid.30 For instance, indocyanine
green-loaded nanoparticles were covalently attached to
surface of S. typhimurium YB1 strain via amide bonds to
form YB1-INPs. YB1-INPs maintained superior targeting
ability for tumor and photothermal effect, which contrib
uted to 14-times bioaccumulation in tumor for significant
tumor elimination without recurrence.31 Amide bonds
were the most frequent strategy to connect with bacteria
by adding carboxyl in the nanoparticles, with superior
stability in vivo. Luo et al.32 also attached perfluorohex
ane-loaded poly (lactic-co-glycolic acid) (PLGA) nanopar
ticles to the surface of anaerobic bifidobacterium longum.
This biohybrid could carry the perfluorohexane to deep
tumor tissues, enhancing the therapeutic effect of highintensity focused ultrasound therapy. Compared with the
amide-bond connection, the imine-bond connection for
biohybrid would cause unstable separation in acid tumor
microenvironment (TME), due to the hydrolysis of imine
bonds in acid solution. However, this strategy could
achieve specific separation of nanoparticles from bacteria
in TME, which cause no effect on the uptake of
nanoparticles by cells. Chen et al.33 prepared
a photosensitizer-loaded nanoparticles (Zeolite imidazole
framework (ZIF-90)), and an imine bond was formed
between the aldehyde group of ZIF-90 and the amino
group of the bacterium to modify the Shewanella mR-1.
After moving into acid tumor tissues, the photosensitizerloaded ZIF-90 fall off from the surface of bacteria and
achieve photothermal and photodynamic antitumor effect
under laser irradiation.
Magnetotactic bacteria can synthesize magnetosomes
(magnetic nanoparticles, usually composed of iron oxide)
inside their cells, which are aligned longitudinally like
compasses to guide magnetotactic bacteria as an excellent
targeting carrier.34 Magnetococcus marinus strain MC-1,
the magneto-aerotactic bacteria, was introduced to trans
port SN-38-loaded liposomes into hypoxic regions of
tumor. The attachment of liposome relied on the covalent
bond between the carboxyl of DSPE-PEG-COOH and the
amino groups on the bacteria surface. By magnetotactic
directional control towards the hypoxic regions of tumor,
the mean tumor targeting ratio (>50%) was achieved to
enhance the efficiency of the targeted chemotherapy. Many
other therapeutic modalities could also benefit from this
delivery strategy, including delivering the radio-sensitizers
or photodynamic sensitizer into the tumor hypoxic regions,
which enhanced the radiotherapeutic or photothermal
treatments. Another study35 further evaluated the effect
International Journal of Nanomedicine 2021:16
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on the swimming speed of magnetotactic bacteria after
attaching the liposomes to the surface. Their research
evidenced a 27% decline of the swimming speed and
higher velocity at the same magnetic field for the biohy
brid, which proved that magnetotactic bacteria could still
assist the nanoparticle to overcome diffusion resistances in
solid tumors by chemical connection.
In addition to the direct attachment, there also
exists another chemical modification strategy in bacteriananomaterial hybrids. Kuru et al.36 exploited a one-sizefits-all strategy to modify the surface of bacteria. They
found unnatural D-amino acids of various sizes and func
tionalities could be incorporated into peptidoglycan (PG)
on the bacteria. By introducing the 7-hydroxycoumarin
3-carboxylic acid (HCC-OH) and 4-chloro-7-nitrobenzo
furazan (NBD-Cl), to a D-amino acid backbone, these
non-toxic D-amino acids preferably label the sites of PG
synthesis, enabling the spatiotemporal tracking of cell
wall.36 This strategy provided more chemical sites for
the nanomaterials to attach on. A typical way is to first
modify the bacteria with azide groups and modify nano
materials with alkyne-strained groups. Then both func
tional groups could form stable triazole bonds by click
reaction. Moreno et al. attached drug-loaded mesoporous
silica nanoparticles to the surface of Escherichia coli bac
teria, which achieved higher penetration in tumoral
matrices and homogeneous distribution of therapeutic
agents inside tumors.37
Compared with other bioconjugation techniques, the
covalent bonds are stronger with the bond dissociation
enthalpy above 300 kJ·mol–1. Hence, during the in vivo
navigation, the biohybrid would likely remain stable until
arriving at tumors. Future studies need to further investi
gate whether nanomaterials undergo detachment from bac
teria in the cellular environment or bacteria /nanomaterial
complexes themselves can be internalized by nonphagocy
tic cells.
Physical Adsorption
Apart from the chemically covalent modification, the phy
sical adsorption was also introduced to fabricate bacteriananoparticle biohybrids, including van der Waals forces,
electrostatic forces, hydrogen bonds, and hydrophobic
effects, etc.38 As is known, the surface of bacteria displays
negative potential, so there appeared some strategies to
reverse the nanomaterial potential from negative to posi
tive via adding cationic polymers or being protonated.
Then the hybrid could be formed by electrostatic
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adsorption forces.38 Polyethylenimine (PEI), as a cationic
polymer, can be combined with nanoparticles by surface
modification, then absorbing to the surface of bacteria. Wu
et al.38 coated a photosensitizer-loaded lipid nanoparticle
onto the surface of E. coli, with the above strategy (PEI,
600Da). This multifunctional hybrid achieved better inva
sion ability for cancer cells and efficient light-mediated
cancer killing (Figure 2). Similarly, Hu and Chen et al.39,40
constructed plasmids encoding the vascular endothelial
growth factor receptor (VEGFR2) gene and antigenic
gene as DNA vaccine. By electrostatic self-assembly of βcyclodextrin-PEI and pDNA as nanoparticles, the DNA
nano-vaccine was decorated on the surface of invasive
Salmonella by electrostatic interaction. The cytotoxic
T lymphocytes (CTLs) are activated for immunotherapy,
which further inhibits the formation of tumor blood vessels
by affecting the VEGFR2 pathway, leading to a thorough
tumor suppression. In fact, bacteria themselves have cer
tain immune-stimulating activity, acting as adjuvants, so
that a DNA vaccine/bacteria hybrid could amplify the
immune activation effect in TME. Other cationic polymers
such as chitosan or cationic peptides may also be suitable
for the binding of complexes. Except for cationic polymer,
protonation can also make the nanoparticles positively
charged. Luo et al.41 used protonated oleic acid to wrap
the imaging agent-loaded nanorods. With the positively
charged surface, the nanorods were combined with anae
robic bifidobacterium breve UCC2003 through electro
static interaction. Through the targeting of bacteria, the
imaging agent concentrated at tumor sites to increase the
Figure 2 (A) Process of PEI employed photosensitizer nanoparticles (TDNPP)-coated live E. coli. (B) Intracellular trafficking of nanoparticle-coated live E. coli and
photosensitizer delivery. Adapted with permission from Wu M, Wu W, Duan Y, Li X, Qi G, Liu B. Photosensitizer Bacteria Biohybrids Promote Photodynamic Cancer Cell
Ablation and intracellular Protein Delivery. Chem Mater. 2019;31(18):7212–7220. Copyright 2019 American Chemical Society.38
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fluorescence intensity in tumor. This strategy could be
applied in various bacteria/nanomaterial construction.
In addition, supramolecular self-assembly is a physical
process in which molecules spontaneously connect into
molecular aggregates with stable structure on the mem
brane surfaces, relying on the intermolecular forces of
non-covalent bonds. Recently, a smart coating method
with lipid membranes based on interfacial supramolecular
self-assembly was found to keep bacteria unbroken during
the first 4 h in the stomach. Then, nearly 90% of the
bacteria disassembled from the coating after 4
h following arrival in the intestines, which in turn results
in the recovery of their inherent properties. This intelli
gent delivery system using FDA approved materials sig
nificantly increased the preservation and bioavailability,
providing a smart delivery strategy for the precise target
ing to intestines.42 Hence, if antitumor drug was loaded
inside the bacteria, this supramolecular self-assembly
strategy could be utilized to target and treat intestinal
tumors.
In general, the passive adsorption through non-covalent
bonds, such as van der Waals forces or electrostatic forces
is easy to form. However, the conjugations may suffer
from poor stability in vivo, especially in plasma. In addi
tion, it should be taken into account that if bacteria pro
liferate in vivo, the absorbed nanoparticles may fall off the
surface. Once the outer layer is lost, most bacteria exposed
in the blood may trigger a type of inflammatory storm.
Therefore, the non-pathogenic probiotics as therapeutic
agent vectors may be a better choice in this kind of
physically adsorbed hybrid.
Biomineralization Process
Biomineralization is a process in which the living organ
isms translate mineral materials into their biological
matrix. It is interesting that some bacteria could biominer
alize nanoparticles by grabbing and turning metal ions into
the element metal through a biological enzymatic process.
Scientists have constructed many kinds of bacteriainorganic composites via this biomimetic mineralization
strategy, which have been applied in many fields such as
sensing, imaging and catalysis. However, there still exists
great potential in therapeutic delivery. Bacteria as a tumortargeting live organism, could also be endowed with var
ious functions in antitumor therapy in this way. First,
biomineralization nanoparticles on the surface of bacteria
would not affect the activity of bacteria as a tumortargeting navigation. Thus, the bacteria-based therapeutic
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Ye et al
platforms by biomineralization could provide a synergetic
option to achieve the tumor-targeting capacity and sup
press tumor by drug-loaded nanoparticles. Various materi
als have been used in biomimetic mineralization on the
surface of bacteria, including ZnS, silica, selenium, iron
oxides, calcium phosphate, gold nanoparticles and metalorganic frameworks (MOF).
First, many metal and metallic oxides have been proved as
photothermal agents for photothermal therapy such as tetra
pyrrolic derivatives of Palladium (II)(WST11), Lu(III)
(Lutex), and Sn(IV) (Purlytin), thereby applying specific bac
teria to biosynthesize the photothermal agents on the surface
could increase the targeting ability of PTT.43 Chen et al.
introduced the facultative anaerobic bacterium Shewanella
oneidensis MR-1 to reduce sodium tetra-chloropalladate
(Na2PdCl4) into Pd nanoparticles on its surface.33,44 This selfmineralized photothermal bacterium was reported to possess
preferential tumor-targeting ability and superior photothermal
properties.45 Wang et al. biosynthesized gold nanoparticles on
the surface of Shewanella algae K3259. This hybrid not only
promoted the targeting of photodynamic therapy of gold nano
particles, but also accelerated bacterial metabolism to improve
the production of antineoplastic tetrodotoxin for antitumor
therapy by transferring photoelectrons produced by AuNPs
into bacterial cytoplasm.46 To extend the loading types, Yan
et al.47 constructed a bacteria@MOF hybrid by biomineralized
Escherichia coli (MG1655) with a zeolitic imidazolate frame
work-8 layer (MOF). Inside MOF, a photosensitizer (chlorin
e6, C) and a chemotherapeutic drug (doxorubicin, D) were
loaded which exhibited synergistically excellent therapeutic
efficacy (Figure 3). Based on this approach, more application
of various therapies could be broadened via loading different
drugs into the drug delivery carriers biosynthesized on the
surface of bacteria, such as MOF, silica nanoparticles, calcium
carbonate or calcium phosphate nanoparticles.
The biomineralization process conjugating the bacteria
with some inorganic nanoparticles gives the drug delivery
systems some unique functions such as magnetic, photo
thermal conversion ability. However, certain amino acids
on the surface of the living agents limited the universality
of the strategy and the morphology needs to be further
studied.48
Other Binding Forms
Other methods of attachment on the bacteria have also
been used such as bioaffinity or specific attachment (e.g.,
antibody-antigen),49,50 in the bacteria-nanoparticle
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Figure 3 (A) Biomimetic mineralization of tumor-targeting E. coli by zeolitic imidazolate framework-8 (ZIF-8) for the delivery of therapeutics. (B–C) TEM images of primary
E. coli and E. coli@ZIF-8/C&D. (D) Tumor growth curves of 4T1 tumor-bearing mice with different treatments (*p <0.05, **p <0.01). Adapted with permission from Yan S,
Zeng X, Wang Y, Liu BF Biomineralization of Bacteria by a Metal-Organic Framework for Therapeutic Delivery Adv Healthcare Mater. 2020;9(12):e2000046. © 2020 WILEYVCH Verlag GmbH & Co. KGaA, Weinheim.47
biohybrids. These relatively close binding forces are the
specific interaction forces already existed in the organism.
First, the affinity between streptavidin and biotin is
a protein–ligand interaction, one of the strongest binding
forces in nature. Biotin could be closely captured by
a tetrameric biotin-binding protein, streptavidin, which is
widely used in the targeting modification on the drug
delivery carrier.51,52 In this strategy, biotin molecules
were always bound to the outer membrane of bacteria by
incubating antibody-modified biotin with bacteria for 1 h,
and streptavidin was covalently attached on the surface of
the nanoparticles. Then the hybrid was formed through the
co-incubation of biotin-labeled bacteria and streptavidincoated nanoparticles. Sahari et al. treated the E. coli
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MG1655m with goat polyclonal anti-lipid A LPS antibody
labeled with biotin, and then streptavidin-coated polymeric
microparticles were decorated on the surface of bacteria.53
Moreover, poly(lactic-co-glycolic acid) nanoparticles were
displayed on the surface of S. typhimurium VNP20009
using a similar strategy. They found the nanoparticle con
jugation did not impede bacteria’s intratumoral transport
performance, even enhancing retention and distribution of
nanoparticles in solid tumors by up to a remarkable 100fold54 (Figure 4). Uthaman et al. have modified the facul
tative anaerobic Salmonella typhimurium following the
genetic transformation to express biotin in order to interact
with streptavidin conjugated microbeads. Via a specific
interaction between the biotin on the bacteria and
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Figure 4 The development of bacteria-enabled autonomous drug delivery system (NanoBEADS) via biotin-streptavidin conjugation. (A) Each NanoBEADS agent is
constructed by conjugating several streptavidin-coated PLGA nanoparticles with a tumor targeting biotinylated-antibody coated S. typhimurium VNP20009, using strepta
vidin–biotin noncovalent affinity-based bonds. NanoBEADS assembly was followed by incubation with mPEG-biotin to quench residual streptavidin binding sites on the
nanoparticles. (B) A representative SEM image of a NanoBEADS agent. (C) Percentage occurrence of NanoBEADS formation at various nanoparticle:bacteria ratios used for
NanoBEADS construction. (D) Distribution of nanoparticle loading of NanoBEADS agents constructed at nanoparticle to bacteria ratio of 100:1. (E) Distribution index (DI)
of PLGA nanoparticles, NanoBEADS, and PEGylated bacteria in 4T1 tumors. Each NanoBEADS agent carries an average of 22 nanoparticles, thus, it enhances the
intratumoral transport of nanoparticles by up to ≈100-fold (*p<0.05). Adapted from Suh S, Jo A, Traore MA, et al. Nanoscale Bacteria-Enabled Autonomous Drug Delivery
System (NanoBEADS) enhancesintratumoral transport of nanomedicine. Adv Sci. 2019;6(3):1801309. © 2018 The Authors. Published by WILEY-VCH Verlag GmbH & Co.
KGaA, Weinheim. This is an open access article distributed under the terms of the Creative Commons CC BY license.54
streptavidin on the HA beads, both chemotactic and bio
logical targeting towards breast tumor cells further
enhanced the targeted antitumor therapy.55 In addition,
the number of bacteria attached on the surface of the
microbeads could be easily controlled which ensured that
the net self-propelling force of all bacteria enables the
microbeads to move in a single direction.
Apart from the streptavidin-biotin affinity, the anti
body-antigen interaction was also designed for the func
tional NPs delivery. The nanoparticles could be fabricated
by modifying with a layer of monoclonal antibody that is
targeted to specific bacteria. According to the principle,
Luo et al.41 first injected the C. difficile spores into tumors,
followed by the injection of the antibody-NP to specifi
cally target the germination of the C. difficile spores (an
antibody-guiding approach). Hence, due to this highly
specific antibody-antigen, the bacteria itself can act as
guiding markers to attract nanomedicines into tumors and
form hybrids in vivo.
International Journal of Nanomedicine 2021:16
Future Opportunities for
Bacteria-Nanoparticle Biohybrids
Against Cancer
Various nanomaterials have been investigated to design the
bacteria/material hybrid drug delivery system for better
antitumor therapy. Among them, the most common ones
are liposomes, micelles, etc., which have significant advan
tages in drug loading and delivery.56,57 In addition, poly
ethylene glycol-modified nanoparticles also act as possible
candidates, attributed to flexible modification and the high
biocompatibility of polyethylene glycol.58–60 Moreover,
a variety of other cargo nanomaterials (e.g., polycaprolac
tone, alginates, chitosan, polystyrene, and cellulose) are
also employed. Generally, aside from the attachment in
our review, the cargo shapes, attachment density, nonhomogeneous patterned attachment of these nanomaterials
on the surface of the bacteria (e.g., Janus-type surfacepatterned coverage) will further affect the bacterial
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swimming speed and sensing ability, thus affecting the
tumor targeting ability. According to the reports, all the
hybrids after modification could achieve the nanomaterials
propulsion speeds ranging from 0.5 μm/s to 30 μm/s. How
these factors influence the movements of hybrids are in the
previous reported review.61
In the future, the biohybrid microrobotic system still
has many challenges. First, as an effective drug delivery
carrier, it must be able to release the drug precisely in
a controlled manner at the tumor area in response to the
specific conditions in the tumor microenvironment, such as
acidic environment, high expression of glucuronidase and
matrix metallase, light or ultrasound, etc. Therefore, more
intelligent nanoparticles reported could be applied into this
hybrid system. Second, it is necessary to avoid the
uncontrollable proliferation of bacteria in the body,
because the induced autoimmune reaction could result in
severe side effects and even death. Although such risk
cases lead scientists to turn to attenuated bacteria and nonpathogenic strains,62,63 the lipopolysaccharide and other
components on the surface of bacteria are still regarded
as risky. Recently, the advanced development of synthetic
biology provides various strategies to control the retention
of bacteria in the body by designing an auxotrophic
bacterium,28 or constructing a suicide circuit inside the
bacterial cells,64,65 which step forward in meeting regula
tory requirements. It is noted Fan et al. constructed chro
mosome-free cell called SimCells (simple cells) from
Escherichia coli, Pseudomonas putida, and Ralstonia
eutropha, via double-stranded breaks made by heterolo
gous I-CeuI endonuclease and the degradation activity of
endogenous nucleases. This method could effectively pre
vent the infinite proliferation of bacterial carrier in the
body.66 In the future, the engineering of bacteria cells
with better safety and even expressing protein drugs
could be combined with nanomaterials, trying to gather
all the characteristics of an ideal drug delivery system in
one bacterium.
Bacteria-Derived Outer Membrane
Based Nanoplatforms
Bacterial outer membrane vesicles (MVs) are secreted by
Gram-negative bacteria with particle sizes ranging from
20–400 nm that participated in diverse biological pro
cesses, including horizontal gene transfer, the export of
cellular metabolites and cell-to-cell communication.67–69
Although other synthetic nano-vectors exhibit similar
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size, the biological structure and function of MVs
endowed it with innate biocompatibility, large drugloading space, high physicochemical stability70 and the
inherent ability to communicate with cells. In addition,
the structure and function of MVs vary from different
species. Some MVs have been reported to have natural
targeting abilities or specifically internalized by endocy
tosis. For example, the MVs derived from Escherichia
coli were shown to successfully penetrate stratum cor
neum and accumulate in dermis, having the superior
targeting and infiltration in melanoma spheroids;71 MVs
obtained from Salmonella and Shigella contain adhesion
which could be recognized, endocytosed, and digested in
gastrointestinal cells without any targeting modification,
providing a targeted delivery therapy for the colon
cancer.72 On the basis of previous study, bacterial MVs
have been successfully used to load different kinds of
antitumor drugs with various structures, hydrophobicity,
charges and solubility, such as DNA, RNA, paclitaxel,
Indocyanine Green (ICG) and TNF-related apoptosis
inducing ligand (TRAIL), which had covered chemother
apy, thermo-therapy and immunotherapy.73–83
It is noted that bacterial MVs contain multiple bacteriaderived immunostimulatory components, such as lipopoly
saccharide (LPS), outer membrane proteins, DNA, RNA
and lipoproteins.67,84 This realization attracted extensive
investigation into whether the treatment of MVs alone
could offer comparable pharmacological antitumor bene
fits. However, the serious systemic inflammatory responses
and rapid clearance were found when given to mice via
intravenous injection. To expand its application, different
strategies have been explored to construct better drug deliv
ery platforms in anticancer immunotherapies.85–87 In this
part, we mainly focus on the design strategies for bacterial
MVs as drug vehicles for better antitumor effect, including
genetic manipulation of biosynthesis to produce endogen
ous species or attaching exogenous species to membrane
surface (Figure 5).
Engineering MVs via Genetic Manipulation
With the advances of synthetic biology, researchers have
introduced non-native materials to bacteria to augment
therapeutic function. It is highly likely that many of
these materials will unwittingly appear within MVs. For
example, the incorporated material expressed on the bac
terial membrane may be packaged into the MVs for secre
tion. Taking advantage of this bacteria engineering
technique, the MVs functionalization could be achieved.
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Figure 5 The illustration of MVs engineered by genetic and non-genetic method for drug loading. Genetic manipulation was taken for reducing pathogenicity, enhancing
targeting ability to tumor and improving anti-tumor immune response; non-genetic engineering modification including biomineralization, chemical bonding and membrane
fusion; the functionalized MVs could load drugs such as chemotherapeutic drugs (e.g., doxorubicin, paclitaxel), nucleic acid (e.g., DNA, siRNA), photosensitizers/
photothermal agents (e.g., ICG) and protein drugs (e.g., TRAIL).
Abbreviation: LPS, Lipopolysaccharides.
Herein, we will discuss how techniques such as genetic
engineering can be exploited for the broader application of
MVs as targeted vehicles towards tumors.
Reduce Pathogenicity of MVs as Drug Carrier
The bacteria MVs still had safety concerns that limited
their clinical application. In addition to vaccines, to be
widely employed in the development of carriers for ther
apeutic agents, various strategies were explored to reduce
their pathogenicity or toxicity.88 Firstly, the MVs used as
carriers were mostly obtained from non-pathogenic strains.
Then, nitrogen cavitation method was exploited to elim
inate intracellular components to form double-layer MVs
from E. coli BL21, thus further reducing the toxicity. To
better act as safe delivery system, the outer membranes of
MVs were also manipulated. As we know, the components
of lipopolysaccharide (LPS), bacterial endotoxin-lipid A,
would cause serious inflammatory responses if injected
International Journal of Nanomedicine 2021:16
systemically. Hence, the genetically mutant bacteria strains
to modify lipid A were engineered. For example, E. coli
K-12 W3110 strain carrying an msbB mutation, was
shown to produce under-acylated LPS and thus exhibits
reduced endotoxicity toward human cells compared with
E. coli strains that produce hexa-acylated LPS.
Additionally, the shorter length of o-polysaccharide in
LPS further reduces immunogenicity.89
Improve Targeting Ability to Tumor
To effectively treat cancers, the MVs have been developed to
target tumor tissue and enhance the therapeutic function via
the design of expressing targeting ligands on the surface. As
reported, the common proteins with selective localization on
surface of MVs includes ClyA,90 hemoglobin protease
(Hbp),91 and outer membrane protein (Omp) A/C/F.
Among that, there is a size limitation of surface display
protein by fusing with Hbp.90 Both of the N- and
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Figure 6 (A) Schematic representation of OMVs expressing HER2-specific affibody (AffiHER2OMV), purified after vesiculation from the parent bacteria and further loaded
with siRNA-TAMRA (AffiHER2OMVsiRNA-TAMRA). (B) Schematic representation of the pGEX4T1-ClyA-Affibody construct. (C) Whole-body in vivo imaging revealed
accumulation of AffiHER2OMVsiRNA-Cy5.5. The circles (red) indicate the tumor position. (D) Tumor growth inhibition (TGI) was monitored in HCC-1954 xenografts, and
AffiHER2OMVsiRNA exerted potent antitumor effects compared with all controls (**p <0.01). Adapted with permission from Gujrati V, Kim S, Kim SH, et al. Bioengineered
Bacterial Outer Membrane Vesicles as Cell-Specific Drug-Delivery Vehicles for Cancer Therapy. ACS Nano. 2014;8(2):1525–1537. Copyright 2014 American Chemical
Society.86
C-terminals of OmpA/C/F are located on the medial side of
the outer membrane, and the insertion of exogenous elements
into the middle of the protein may influence the protein
structure and folding, especially for the transmembrane
proteins.92,93 In current studies, ClyA was often selected as
the anchor site for surface modification. Recent studies
reported that genetic fusion between recombinant polypep
tides and the C terminus of ClyA in bacteria results in
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a specific display of protein on the surface of MVs, which
could modify the physicochemical property of MVs
surfaces.94 For example, Vipul Gujrati86 utilized the addres
sing ability of ClyA to display a high-affinity anti-human
epidermal growth factor receptor 2 (HER2) affibody in the
MV surface for the purpose of targeted delivery of therapeu
tic siRNA targeting kinesin spindle protein (Figure 6). Gao
et al.95 exploited and expressed RGD4C-EGFP at the
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C-terminus of ClyA on the surface of MVs, to monitor and
enhance the tumor targeting by specifically identifying and
interacting with Integrin αvβ3 on tumor cell. After packing
DOX into the above MVs, they showed promising potential
in tumor growth inhibition. Overall, despite some concerns
over gene transfer and contamination, genetic manipulation
represents a highly accessible strategy for the presentation of
flexible targeting function with MVs.
Enhance the Immune Response
It has been reported that MVs could effectively activate
immunotherapy for cancer treatment. Two MVs-based
vaccines, Bexsero and MeNZB, have been approved for
treatment against meningococcal group B infections,
which highlighted the potential in tumor vaccines. Based
on the PAMPs inside MVs, they gradually developed as
cancer vaccine adjuvants to stimulate dendritic cell (DC)
maturation and promote cytokine release. Besides Toll-like
receptors (TLR) agonists (TLR4, TLR2, TLR596–99), the
STING agonists were also found in MVs components to
produce the strong innate DC stimulation and type
I interferon (IFN) secretion, such as the natural stimulator
cyclic-dinucleotides (CDNs) from MVs.88 Recently,
genetic engineering MVs could exhibit exogenous antigen
protein, provoke antigen-specific immune response and
combat tumor, such as ovalbumin fragment100 and basic
fibroblast growth factor.101 The tumor antigen HPV16E7
was embedded on the surface as well as in the lumen of
E. coli-derived MVs through the location ability of
ClyA.102 This kind of strategy provided a novel vaccine
delivery vector, which could be used to deliver more
neoantigens to induce specific antitumor immune response
effectively. Cheng et al. further employed the protein Plugand-Display system to display various target antigens,
including a SpyTag (SpT)/SpyCatcher (SpC) pair103 and
a SnoopTag (SnT)/SnoopCatcher (SnC) pair,104 in which
the protein tag can spontaneously bind to the protein
catcher through isopeptide bond formation, by expressing
the protein catchers as fusion proteins with ClyA, various
tumor antigens linked to protein tags can be rapidly dis
played on the MVs surface, eliciting a long-term immune
memory in vivo.105
Besides the potential in tumor vaccine, the modified MVs
were also applied in other immunotherapies. Tumor environ
ment is a complex collection with unique immune escape
mechanism, so the IFN-γ-mediated anti-tumor immunity87
by MVs itself may be limited by the form of IFN-γresponsive programmed cell death-Ligand 1 (PD-L1)
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expression on tumor cells to suppress the function of
T cells,106 which eventually leads to immune tolerance. The
strategy of MVs combined with other strategies to reverse the
immune suppression could overcome the obstacle. For
instance, the MVs expressing the ectodomain of pro
grammed cell death-1 (PD-1) on the surface integrated both
immune activation and blockage of the immunosuppression,
leading to a significant reduction of tumor growth in color
ectal cancer models.107 Based on the flexible manipulation,
reversing other immunosuppressive factors such as CD47,
OX40, TIM-3 and LAG-3 can also use the MVs platform to
explore more combination in antitumor immunotherapy.
Modification of MVs by Non-Genetic
Engineering Strategy
Considering the specific characteristics of the surface of
MVs, many other non-genetic engineering modification
methods can be introduced to optimize MVs for safer
therapy and better antitumor effect. To selectively expose
the MVs in TME, the “shielding” strategy by wrapping
MVs inside highly biocompatible materials was explored,
by biomineralization, chemical bonding, or membrane
fusion. Considering the similar structure of outer mem
brane vesicle as liposomes, chemical modifications can
also be introduced to modify them. However, this related
work is rarely reported. Other modification strategies are
summarized. For instance, Qing et al. biosynthesized
a highly biocompatible calcium phosphate on the surface
to encapsulate OMVs. Upon their arrival at tumor sites,
the slightly acidic pH of TME triggered the dissolution of
CaP shells and release MVs to activate immune response.
Moreover, they further doped folic acid into CaP shells to
enhanced the tumor targeting.85 Referred to the similar
structure of various cell membranes, membrane fusion
technology was used to achieve the fusion of two natural
biomembranes, even the fusion of MVs with liposomes.
Wang et al.108 fused MVs with the cancer cell membrane
to generate a hybrid membrane, which simultaneously
harnessed the homing ability of cancer cell membrane
and immune response activation ability of bacterial MVs
to synergistically eradicate melanoma. The strategy could
be adapted to combine immunotherapy with various thera
pies toward different cancers by fusing the bacterial MVs
with various cancer cell membranes and incorporating
different therapeutic agents inside MVs (Figure 7). In
addition, due to the similar lipid nature, DSPE-PEGRGD was reported to have been fused into the lipid
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Figure 7 (A) Schematic of the membrane derived from OMV and cancer cell (CC) fusion and the resulting fused membrane camouflaged HPDA NPs to produce HPDA@
[OMV-CC] NPs. (B) Temperature elevation of HPDA NPs and HPDA@[OMV-CC] NPs (100 μg/mL). (C) CLSM image of NHDF cells, MCF-7 cells, and B16-F10 cells stained
with Hoechst 33342 and cultured with DiI-dyed HPDA@[OMV-CC] NPs. Adapted with permission from Wang D, Liu C, You S, et al. Bacterial vesicle-cancer cell
hybridmembrane-coated nanoparticles for tumor specific immune activationand photothermal therapy. ACS Appl Mater Interfaces. 2020;12(37):41138–41147. Copyright
2020 American Chemical Society.108
membrane of MVs with lipid head of DSPE by extrusion
technology,109 endowing MVs with better targeting ability.
The same method was also applied to coating MVs on
Tegafur-loaded nanomicelles, to exert both chemothera
peutic and immunomodulatory roles for better cancer
immunotherapy.110
Future and Prospects
Bacteria-related drug delivery systems (DDS) in anticancer
therapy have been researched for over a century and this field
has developed rapidly in recent years with advances in syn
thetic biology and chemistry. Different from the EPR effect
of other nanoparticles, its homing ability is more conducive
to penetrating physiological barriers and tumor tissues.
Moreover, based on various modification strategies, the
safety issues and low therapeutic efficiency have also been
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greatly improved, holding larger potential as auspicious can
didates for therapeutic and drug-delivery applications in
tumor field.32,54 From this systematic review we conclude
that there will be an increasing use of bacteria-related drug
delivery systems (DDS) for drug delivery in cancer treat
ment, along with an extensive application into various anti
tumor therapies. New strategies would be designed based on
the previous studies, for example, we could manipulate bac
teria that express specific molecules at the hypoxia tumor
microenvironment via genetic manipulation, which could
synergize with chemotherapeutic drug loaded in the nano
materials for high anti-tumor efficacy.
Although the bacteria-related DDS has been widely inves
tigated in preclinical studies, many challenges still remain in
the way to further clinical application. First, the risk of the
bacteria-related drug delivery system application should be
International Journal of Nanomedicine 2021:16
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further considered. And safer bacteria, stable conjugation
between bacteria and nanoparticles, and comprehensive eva
luation of their safety are needed. Next, more investigations on
the controllability, stability and reproducibility of the prepara
tion techniques should be conducted, e.g., the binding site,
number of conjugated bacteria and nanoparticles, and the
strength of conjugation.
Furthermore, the reports on the stability, metabolism and
clearance, drug loading, retention in vivo, pharmaceutical
stability during storage, pharmacokinetics (PK), biodistribu
tion and Current Good Manufacturing Practices (cGMP) of
clinical batches for this DDS were scarce, which still have
a long way to go for accumulation of more data. Additionally,
the standardization and regulations of the manufacturing for
this DDS are less well defined due to the risk and diversity,
which involves a complex set of programs and different
fields, such as bioengineering and multifactorial biological
processes. Deeper investigation on the intracellular mechan
isms and distribution inside cells will also provide reference
data for regulatory guidelines. What is more, efforts should
be taken to improve the methods of in vitro characterization,
which will favor the investigation on the in vitro and in vivo
pharmacokinetics correlation of this DDS and promote the
process of their clinical applications.
Acknowledgments
The authors would like to thank Nanjing Normal
University and China Pharmaceutical University for pro
viding supporting and facilities. The work was supported
by grants from the National Natural Science Foundation of
China (NO. 81972892).
Disclosure
The authors report no conflicts of interest in this work.
References
1. Couvreur P. Nanoparticles in drug delivery: past, present and future.
Adv
Drug
Deliv
Rev.
2013;65(1):21–23.
doi:10.1016/j.
addr.2012.04.010
2. Mohammadinejad R, Dehshahri A, Sagar Madamsetty V, et al. In vivo
gene delivery mediated by non-viral vectors for cancer therapy.
J Control Release. 2020;325:249–275.
3. Delfi M, Sartorius R, Ashrafizadeh M, et al. Self-assembled peptide
and protein nanostructures for anti-cancer therapy: targeted delivery,
stimuli-responsive devices and immunotherapy. Nano Today. 2021;38.
4. Caffery B, Lee JS, Alexander-Bryant AA. Vectors for glioblastoma
gene therapy: viral & non-viral delivery strategies. Nanomaterials.
2019;9(1):105. doi:10.3390/nano9010105
5. Chang WW, Lee CH. Salmonella as an innovative therapeutic anti
tumor agent. Int J Mol Sci. 2014;15(8):14546–14554. doi:10.3390/
ijms150814546
International Journal of Nanomedicine 2021:16
Ye et al
6. Panteli JT, Forbes NS. Engineered bacteria detect spatial profiles in
glucose concentration within solid tumor cell masses. Biotechnol
Bioeng. 2016;113(11):2474–2484. doi:10.1002/bit.26006
7. Pawelek JM, Low KB, Bermudes D. Bacteria as tumour-targeting
vectors. Lancet Oncol. 2003;4(9):548–556. doi:10.1016/S14702045(03)01194-X
8. Bone RC. Toward an epidemiology and natural history of SIRS
(systemic inflammatory response syndrome). JAMA. 1992;268
(24):3452–3455. doi:10.1001/jama.1992.03490240060037
9. Dinarello CA, Gelfand JA, Wolff SM. Anticytokine strategies in the
treatment of the systemic inflammatory response syndrome. JAMA.
1993;269(14):1829–1835. doi:10.1001/jama.1993.03500140081040
10. Gericke D, Engelbart K. Oncolysis by Clostridia. ii. experiments
on a tumor spectrum with a variety of clostridia in combination
with heavy metal. Cancer Res. 1964;24:217–221.
11. Singh AV, Sitti M. Targeted drug delivery and imaging using
mobile milli/microrobots: a promising future towards theranostic
pharmaceutical
design.
Curr
Pharm
Des.
2016;22
(11):1418–1428. doi:10.2174/1381612822666151210124326
12. Cao ZP, Liu JY. Bacteria and bacterial derivatives as drug carriers
for cancer therapy. J Control Release. 2020;326:396–407.
doi:10.1016/j.jconrel.2020.07.009
13. DeWeerdt S. BACTERIOLOGY A caring culture. Nature.
2013;504(7480):S4–S5. doi:10.1038/504S4a
14. Prout GR. Intracavitary bacillus Calmette-Guerin in the treatment
of superficial bladder tumors - comment. J Urol. 2002;167
(2):893–894.
15. Prout GR. Intracavitary bacillus Calmette-Guerin in the treatment
of superficial bladder tumors comment. J Urol. 2017;197(2):
S144–S145.
16. Biot C, Rentsch CA, Gsponer JR, et al. Preexisting BCG-specific
T cells improve intravesical immunotherapy for bladder cancer. Sci
Transl Med. 2012;4(137):137ra172. doi:10.1126/scitranslmed.3
003586
17. Clairmont C, Lee KC, Pike J, et al. Biodistribution and genetic
stability of the novel antitumor agent VNP20009, a genetically
modified strain of Salmonella typhimurium. J Infect Dis.
2000;181(6):1996–2002. doi:10.1086/315497
18. Toso JF, Gill VJ, Hwu P, et al. Phase I study of the intravenous
administration of attenuated Salmonella typhimurium to patients
with metastatic melanoma. J Clin Oncol. 2002;20(1):142–152.
doi:10.1200/JCO.2002.20.1.142
19. Staedtke V, Roberts NJ, Bai RY, Zhou S. Clostridium novyi-NT in
cancer therapy. Genes Dis. 2016;3(2):144–152. doi:10.1016/j.
gendis.2016.01.003
20. Agrawal N, Bettegowda C, Cheong I, et al. Bacteriolytic therapy
can generate a potent immune response against experimental
tumors. Proc Natl Acad Sci U S A. 2004;101(42):15172.
doi:10.1073/pnas.0406242101
21. Staedtke V, Bai R-Y, Sun W, et al. Clostridium novyi-NT can
cause regression of orthotopically implanted glioblastomas in
rats. Oncotarget. 2015;6(8):5536–5546.
22. Gniadek TJ, Augustin L, Schottel J, Leonard A, Batist G. A phase
I, dose escalation, single dose trial of oral attenuated Salmonella
typhimurium containing human IL-2 in patients with metastatic
gastrointestinal cancers. J Immunother. 2020;43(7):217–221.
doi:10.1097/CJI.0000000000000325
23. Flickinger JC Jr, Rodeck U, Snook AE. Listeria monocytogenes
as a vector for cancer immunotherapy: current understanding and
progress. Vaccines. 2018;6(3):48. doi:10.3390/vaccines6030048
24. Gunn GR, Zubair A, Peters C, Pan ZK, Wu TC, Paterson Y. Two
Listeria monocytogenes vaccine vectors that express different
molecular forms of human papilloma virus-16 (HPV-16) E7
induce qualitatively different T cell immunity that correlates
with their ability to induce regression of established tumors
immortalized by HPV-16. J Immunol. 2001;167(11):6471–6479.
https://doi.org/10.2147/IJN.S329855
DovePress
Powered by TCPDF (www.tcpdf.org)
8083
�Dovepress
Ye et al
25. Shahabi V, Reyes-Reyes M, Wallecha A, Rivera S, Paterson Y,
Maciag P. Development of a Listeria monocytogenes based vac
cine against prostate cancer. Cancer Immunol Immunother.
2008;57(9):1301–1313. doi:10.1007/s00262-008-0463-z
26. Singh R, Dominiecki ME, Jaffee EM, Paterson Y. Fusion to
Listeriolysin O and delivery by Listeria monocytogenes enhances
the immunogenicity of HER-2/neu and reveals subdominant epi
topes in the FVB/N mouse. J Immunol. 2005;175(6):3663–3673.
doi:10.4049/jimmunol.175.6.3663
27. Brahmer JR, Johnson ML, Cobo M, et al. JNJ-64041757 (JNJ757), a live, attenuated, double-deleted Listeria monocytogenes–
based immunotherapy in patients with NSCLC: results from two
phase 1 studies. JTO Clin Res Rep. 2021;2(2):100103.
doi:10.1016/j.jtocrr.2020.100103
28. Leventhal DS, Sokolovska A, Li N, et al. Immunotherapy with
engineered bacteria by targeting the STING pathway for
anti-tumor immunity. Nat Commun. 2020;11(1):2739.
doi:10.1038/s41467-020-16602-0
29. Lee BK, Yun YH, Park K. Smart nanoparticles for drug delivery:
boundaries and opportunities. Chem Eng Sci. 2015;125:158–164.
doi:10.1016/j.ces.2014.06.042
30. Yan X, Zhou Q, Vincent M, et al. Multifunctional biohybrid
magnetite microrobots for imaging-guided therapy. Sci Robot.
2017;2(12). doi:10.1126/scirobotics.aaq1155
31. Chen F, Zang Z, Chen Z, et al. Nanophotosensitizer-engineered
Salmonella
bacteria
with
hypoxia
targeting
and
photothermal-assisted mutual bioaccumulation for solid tumor
therapy.
Biomaterials.
2019;214:119226.
doi:10.1016/j.
biomaterials.2019.119226
32. Luo Y, Xu D, Gao X, et al. Nanoparticles conjugated with
bacteria targeting tumors for precision imaging and therapy.
Biochem Biophys Res Commun. 2019;514(4):1147–1153.
doi:10.1016/j.bbrc.2019.05.074
33. Chen QW, Liu XH, Fan JX, et al. Self-mineralized photothermal
bacteria hybridizing with mitochondria-targeted metal-organic
frameworks for augmenting photothermal tumor therapy. Adv
Funct Mater. 2020;30(14):1909806.
34. Felfoul O, Mohammadi M, Taherkhani S, et al. Magnetoaerotactic bacteria deliver drug-containing nanoliposomes to
tumour hypoxic regions. Nat Nanotechnol. 2016;11
(11):941–947. doi:10.1038/nnano.2016.137
35. Taherkhani S, Mohammadi M, Daoud J, Martel S, Tabrizian M.
Covalent binding of nanoliposomes to the surface of magneto
tactic bacteria for the synthesis of self-propelled therapeutic
agents. ACS Nano. 2014;8(5):5049–5060. doi:10.1021/
nn5011304
36. Kuru E, Hughes HV, Brown PJ, et al. In situ probing of newly
synthesized peptidoglycan in live bacteria with FluorescentDamino acids. Angew Chem Int Ed. 2012;51(50):12519–12523.
doi:10.1002/anie.201206749
37. Moreno VM, Alvarez E, Izquierdo-Barba I, Baeza A, SerranoLopez J, Vallet-Regi M. Bacteria as nanoparticles carrier for
enhancing penetration in a tumoral matrix model. Adv Mater
Interfaces. 2020;7(11):1901942.
38. Wu M, Wu W, Duan Y, Li X, Qi G, Liu B. Photosensitizerbacteria biohybrids promote photodynamic cancer cell ablation
and intracellular protein delivery. Chem Mater. 2019;31
(18):7212–7220. doi:10.1021/acs.chemmater.9b01518
39. Hu Q, Wu M, Fang C, et al. Engineering nanoparticle-coated
bacteria as oral DNA vaccines for cancer immunotherapy.
Nano
Lett.
2015;15(4):2732–2739.
doi:10.1021/acs.
nanolett.5b00570
40. Chen J, Shen C, Zheng C, et al. Study of properties of VEGFR2
active site and binding mode of VEGFR2 and its inhibitors. Acta
Chim Sin. 2007;65(6):547–552.
8084
Powered by TCPDF (www.tcpdf.org)
https://doi.org/10.2147/IJN.S329855
DovePress
41. Luo CH, Huang CT, Su CH, Yeh CS. Bacteria-mediated
hypoxia-specific delivery of nanoparticles for tumors imaging
and therapy. Nano Lett. 2016;16(6):3493–3499. doi:10.1021/acs.
nanolett.6b00262
42. Wang XY, Cao ZP, Zhang MM, Meng L, Ming ZZ, Liu JY.
Bioinspired oral delivery of gut microbiota by self-coating with
biofilms. Sci Adv. 2020;6(26):eabb1952.
43. Imberti C, Zhang P, Huang H, Sadler PJ. New designs for photo
therapeutic transition metal complexes. Angew Chem Int Ed Engl.
2020;59(1):61–73. doi:10.1002/anie.201905171
44. De Windt W, Aelterman P, Verstraete W. Bioreductive deposition
of palladium (0) nanoparticles on Shewanella oneidensis with
catalytic activity towards reductive dechlorination of polyschlori
nated biphenyls. Environ Microbiol. 2005;7(3):314–325.
doi:10.1111/j.1462-2920.2005.00696.x
45. Chen X, Shi S, Wei J, Chen M, Zheng N. Two-dimensional
Pd-based nanomaterials for bioapplications. Sci Bull. 2017;62
(8):579–588. doi:10.1016/j.scib.2017.02.012
46. Wang X-N, Niu M-T, Fan J-X, Chen Q-W, Zhang X-Z.
Photoelectric bacteria enhance the in situ production of tetrodo
toxin for antitumor therapy. Nano Lett. 2021;21(10):4270–4279.
doi:10.1021/acs.nanolett.1c00408
47. Yan S, Zeng X, Wang Y, Liu BF. Biomineralization of bacteria by
a metal-organic framework for therapeutic delivery. Adv
Healthcare
Mater.
2020;9(12):e2000046.
doi:10.1002/
adhm.202000046
48. Chu C, Su M, Zhu J, et al. Metal-organic framework
nanoparticle-based biomineralization: a new strategy toward can
cer treatment. Theranostics. 2019;9(11):3134–3149. doi:10.7150/
thno.33539
49. Zheng S, Han J-W, Seong Y, Choi Y, Jin P. Active
tumor-therapeutic liposomal bacteriobot combining a drug
(paclitaxel)-encapsulated liposome with targeting bacteria
(Salmonella Typhimurium). Sens Actuators B Chem.
2016;224:217–224. doi:10.1016/j.snb.2015.09.034
50. Traore MA, Damico CM, Behkam B. Biomanufacturing and
self-propulsion dynamics of nanoscale bacteria-enabled autono
mous delivery systems. Appl Phys Lett. 2014;105(17):121.
doi:10.1063/1.4900641
51. Goldenberg DM, Sharkey RM, Paganelli G, Barbet J, Chatal JF.
Antibody pretargeting advances cancer radioimmunodetection
and radioimmunotherapy. J Clin Oncol. 2006;24(5):823–834.
doi:10.1200/JCO.2005.03.8471
52. Park SJ, Park SH, Cho S, et al. New paradigm for tumor ther
anostic methodology using bacteria-based microrobot. Sci Rep.
2013;3:3394. doi:10.1038/srep03394
53. Sahari A, Traore MA, Scharf BE, Behkam B. Directed transport
of bacteria-based drug delivery vehicles: bacterial chemotaxis
dominates particle shape. Biomed Microdevices. 2014;16
(5):717–725. doi:10.1007/s10544-014-9876-y
54. Suh S, Jo A, Traore MA, et al. Nanoscale Bacteria-Enabled
Autonomous Drug Delivery System (NanoBEADS) enhances
intratumoral transport of nanomedicine. Adv Sci. 2019;6
(3):1801309.
55. Uthaman S, Zheng S, Han J, et al. Preparation of engineered
Salmonella Typhimurium-driven hyaluronic-acid-based microbe
ads with both chemotactic and biological targeting towards breast
cancer cells for enhanced anticancer therapy. Adv Healthcare
Mater. 2016;5(2):288–295. doi:10.1002/adhm.201500556
56. Kojima M, Zhang Z, Nakajima M, Ooe K, Fukuda T.
Construction and evaluation of bacteria-driven liposome. Sens
Actuators
B
Chem.
2013;183:395–400.
doi:10.1016/j.
snb.2013.03.127
57. Zhang Z, Li Z, Yu W, Li K, Xie Z, Shi Z. Propulsion of liposomes
using bacterial motors. Nanotechnology. 2013;24(18):185103.
doi:10.1088/0957-4484/24/18/185103
International Journal of Nanomedicine 2021:16
�Dovepress
58. Cho S, Park SJ, Ko SY, Park JO, Park S. Development of
bacteria-based microrobot using biocompatible poly(ethylene
glycol).
Biomed
Microdevices.
2012;14(6):1019–1025.
doi:10.1007/s10544-012-9704-1
59. Rabanel JM, Hildgen P, Banquy X. Assessment of PEG on poly
meric particles surface, a key step in drug carrier translation.
J
Control
Release.
2014;185:71–87.
doi:10.1016/j.
jconrel.2014.04.017
60. Kolate A, Baradia D, Patil S, Vhora I, Kore G, Misra A. PEG a versatile conjugating ligand for drugs and drug delivery
systems. J Control Release. 2014;192:67–81. doi:10.1016/j.
jconrel.2014.06.046
61. Hosseinidoust Z, Mostaghaci B, Yasa O, Park BW, Singh AV,
Sitti M. Bioengineered and biohybrid bacteria-based systems for
drug delivery. Adv Drug Deliv Rev. 2016;106(Pt A):27–44.
62. Fox ME, Lemmon MJ, Mauchline ML, et al. Anaerobic bacteria
as a delivery system for cancer gene therapy: in vitro activation of
5-fluorocytosine by genetically engineered clostridia. Gene Ther.
1996;3(2):173–178.
63. Moese JR, Moese G. Oncolysis by clostridia. i. activity of clos
tridium butyricum (M-55) and other nonpathogenic clostridia
against the Ehrlich carcinoma. Cancer Res. 1964;24:212–216.
64. Gurbatri CR, Lia I, Vincent R, et al. Engineered probiotics for
local tumor delivery of checkpoint blockade nanobodies. Sci
Transl Med. 2020;12(530). doi:10.1126/scitranslmed.aax0876
65. Din MO, Danino T, Prindle A, et al. Synchronized cycles of
bacterial lysis for in vivo delivery. Nature. 2016;536
(7614):81–85. doi:10.1038/nature18930
66. Fan C, Davison PA, Habgood R, et al. Chromosome-free bacterial
cells are safe and programmable platforms for synthetic biology.
Proc Natl Acad Sci. 2020;117(12):6752. doi:10.1073/
pnas.1918859117
67. Schwechheimer C, Kuehn MJ. Outer-membrane vesicles from
gram-negative bacteria: biogenesis and functions. Nat Rev
Microbiol. 2015;13(10):605–619. doi:10.1038/nrmicro3525
68. Brown L, Wolf JM, Prados-Rosales R, Casadevall A. Through the
wall: extracellular vesicles in gram-positive bacteria, mycobac
teria and fungi. Nat Rev Microbiol. 2015;13(10):620–630.
doi:10.1038/nrmicro3480
69. Orench-Rivera N, Kuehn MJ. Environmentally controlled bacter
ial vesicle-mediated export. Cell Microbiol. 2016;18
(11):1525–1536. doi:10.1111/cmi.12676
70. Clayton A, Harris CL, Court J, Mason MD, Morgan BP. Antigenpresenting cell exosomes are protected from complement-mediated
lysis by expression of CD55 and CD59. Eur J Immunol. 2003;33
(2):522–531. doi:10.1002/immu.200310028
71. Peng LH, Wang MZ, Chu Y, et al. Engineering bacterial outer
membrane vesicles as transdermal nanoplatforms for
photo-TRAIL-programmed therapy against melanoma. Sci Adv.
2020;6(27):eaba2735. doi:10.1126/sciadv.aba2735
72. Torchilin VP. Passive and active drug targeting: drug delivery
to tumors as an example. Handb Exp Pharmacol.
2010;197:3–53.
73. MacDiarmid JA, Langova V, Bailey D, et al. Targeted doxor
ubicin delivery to brain tumors via minicells: proof of principle
using dogs with spontaneously occurring tumors as a model.
PLoS
One.
2016;11(4):e0151832.
doi:10.1371/journal.
pone.0151832
74. Solomon BJ, Desai J, Rosenthal M, et al. A first-time-in-human
Phase I clinical trial of bispecific antibody-targeted,
paclitaxel-packaged bacterial minicells. PLoS One. 2015;10(12):
e0144559. doi:10.1371/journal.pone.0144559
75. Yu B, Tai HC, Xue W, Lee LJ, Lee RJ. Receptor-targeted nano
carriers for therapeutic delivery to cancer. Mol Membr Biol.
2010;27(7):286–298. doi:10.3109/09687688.2010.521200
International Journal of Nanomedicine 2021:16
Ye et al
76. Sagnella SM, Yang L, Stubbs GE, et al. Cyto-immuno-therapy for
cancer: a pathway elicited by tumor-targeted, cytotoxic
drug-packaged bacterially derived nanocells. Cancer Cell.
2020;37(3):354–370.e357. doi:10.1016/j.ccell.2020.02.001
77. Sagnella SM, Trieu J, Brahmbhatt H, et al. Targeted
doxorubicin-loaded bacterially derived nano-cells for the treat
ment of neuroblastoma. Mol Cancer Ther. 2018;17
(5):1012–1023. doi:10.1158/1535-7163.MCT-17-0738
78. Alfaleh MA, Howard CB, Sedliarou I, et al. Targeting mesothe
lin receptors with drug-loaded bacterial nanocells suppresses
human mesothelioma tumour growth in mouse xenograft
models. PLoS One. 2017;12(10):e0186137. doi:10.1371/journal.
pone.0186137
79. Whittle JR, Lickliter JD, Gan HK, et al. First in human nanotech
nology doxorubicin delivery system to target epidermal growth
factor receptors in recurrent glioblastoma. J Clin Neurosci.
2015;22(12):1889–1894. doi:10.1016/j.jocn.2015.06.005
80. MacDiarmid JA, Mugridge NB, Weiss JC, et al. Bacterially
derived 400 nm particles for encapsulation and cancer cell target
ing of chemotherapeutics. Cancer Cell. 2007;11(5):431–445.
doi:10.1016/j.ccr.2007.03.012
81. Gujrati V, Prakash J, Malekzadeh-Najafabadi J, et al.
Bioengineered bacterial vesicles as biological nano-heaters for
optoacoustic imaging. Nat Commun. 2019;10(1):1114.
doi:10.1038/s41467-019-09034-y
82. Riley PA. Melanin. Int J Biochem Cell Biol. 1997;29
(11):1235–1239. doi:10.1016/S1357-2725(97)00013-7
83. Liu Y, Ai K, Liu J, Deng M, He Y, Lu L. Dopamine-melanin
colloidal nanospheres: an efficient near-infrared photothermal
therapeutic agent for in vivo cancer therapy. Adv Mater.
2013;25(9):1353–1359. doi:10.1002/adma.201204683
84. Kaparakis-Liaskos M, Ferrero RL. Immune modulation by bac
terial outer membrane vesicles. Nat Rev Immunol. 2015;15
(6):375–387. doi:10.1038/nri3837
85. Qing S, Lyu C, Zhu L, et al. Biomineralized bacterial outer
membrane vesicles potentiate safe and efficient tumor microen
vironment reprogramming for anticancer therapy. Adv Mater.
2020;32(47):e2002085. doi:10.1002/adma.202002085
86. Gujrati V, Kim S, Kim SH, et al. Bioengineered bacterial outer
membrane vesicles as cell-specific drug-delivery vehicles for cancer
therapy. ACS Nano. 2014;8(2):1525–1537. doi:10.1021/nn405724x
87. Kim OY, Park HT, Dinh NTH, et al. Bacterial outer membrane
vesicles suppress tumor by interferon-γ-mediated antitumor response.
Nat Commun. 2017;8(1):626. doi:10.1038/s41467-017-00729-8
88. Kato K, Omura H, Ishitani R, Nureki O. Cyclic GMP-AMP as an
endogenous second messenger in innate immune signaling by
cytosolic DNA. Annu Rev Biochem. 2017;86:541–566.
doi:10.1146/annurev-biochem-061516-044813
89. Li RZ, Liu Q. Engineered bacterial outer membrane vesicles as
multifunctional delivery platforms. Front Mater. 2020;7.
doi:10.3389/fmats.2020.00202
90. Lee SY, Choi JH, Xu Z. Microbial cell-surface display. Trends
Biotechnol. 2003;21(1):45–52. doi:10.1016/S0167-7799(02)00006-9
91. Gerritzen MJH, Martens DE, Wijffels RH, van der Pol L,
Stork M. Bioengineering bacterial outer membrane vesicles as
vaccine platform. Biotechnol Adv. 2017;35(5):565–574.
doi:10.1016/j.biotechadv.2017.05.003
92. Baslé A, Rummel G, Storici P, Rosenbusch JP, Schirmer T.
Crystal structure of osmoporin OmpC from E. coli at 2.0 A.
J Mol Biol. 2006;362(5):933–942. doi:10.1016/j.jmb.2006.08.002
93. Pautsch A, Schulz GE. Structure of the outer membrane protein
A transmembrane domain. Nat Struct Biol. 1998;5
(11):1013–1017. doi:10.1038/2983
94. Kim JY, Doody AM, Chen DJ, et al. Engineered bacterial outer
membrane vesicles with enhanced functionality. J Mol Biol.
2008;380(1):51–66. doi:10.1016/j.jmb.2008.03.076
https://doi.org/10.2147/IJN.S329855
DovePress
Powered by TCPDF (www.tcpdf.org)
8085
�Dovepress
Ye et al
95. Gao J, Wang S, Dong X, Wang Z. RGD-expressed bacterial
membrane-derived nanovesicles enhance cancer therapy via mul
tiple tumorous targeting. Theranostics. 2021;11(7):3301–3316.
doi:10.7150/thno.51988
96. Russo AJ, Behl B, Banerjee I, Rathinam VAK. Emerging insights
into noncanonical inflammasome recognition of microbes. J Mol
Biol. 2018;430(2):207–216. doi:10.1016/j.jmb.2017.10.003
97. Hayashi F, Smith KD, Ozinsky A, et al. The innate immune
response to bacterial flagellin is mediated by toll-like receptor 5.
Nature. 2001;410(6832):1099–1103. doi:10.1038/35074106
98. Oliveira-Nascimento L, Massari P, Wetzler LM. The role of TLR2
in infection and immunity. Front Immunol. 2012;3:79.
doi:10.3389/fimmu.2012.00079
99. Kuzmich NN, Sivak KV, Chubarev VN, Porozov YB, SavateevaLyubimova TN, Peri F. TLR4 signaling pathway modulators as
potential therapeutics in inflammation and sepsis. Vaccines.
2017;5(4):34.
100. Carleton HA, Lara-Tejero M, Liu X, Galán JE. Engineering the
type III secretion system in non-replicating bacterial minicells for
antigen delivery. Nat Commun. 2013;4(1):1590. doi:10.1038/
ncomms2594
101. Huang W, Shu C, Hua L, et al. Modified bacterial outer mem
brane vesicles induce autoantibodies for tumor therapy. Acta
Biomater. 2020;108:300–312. doi:10.1016/j.actbio.2020.03.030
102. Wang S, Huang W, Li K, et al. Engineered outer membrane
vesicle is potent to elicit HPV16E7-specific cellular immunity in
a mouse model of TC-1 graft tumor. Int J Nanomedicine.
2017;12:6813–6825. doi:10.2147/IJN.S143264
103. Zakeri B, Fierer JO, Celik E, et al. Peptide tag forming a rapid
covalent bond to a protein, through engineering a bacterial
adhesin. Proc Natl Acad Sci U S A. 2012;109(12):E690–E697.
doi:10.1073/pnas.1115485109
104. Veggiani G, Nakamura T, Brenner MD, et al. Programmable poly
proteams built using twin peptide superglues. Proc Natl Acad Sci
U S A. 2016;113(5):1202–1207. doi:10.1073/pnas.1519214113
105. Cheng K, Zhao R, Li Y, et al. Bioengineered bacteria-derived
outer membrane vesicles as a versatile antigen display platform
for tumor vaccination via plug-and-display technology. Nat
Commun. 2021;12(1):2041. doi:10.1038/s41467-021-22308-8
106. Garcia-Diaz A, Shin DS, Moreno BH, et al. Interferon receptor
signaling pathways regulating PD-L1 and PD-L2 expression. Cell
Rep. 2019;29(11):3766. doi:10.1016/j.celrep.2019.11.113
107. Li Y, Zhao R, Cheng K, et al. Bacterial outer membrane vesicles
presenting programmed death 1 for improved cancer immunother
apy via immune activation and checkpoint Inhibition. ACS Nano.
2020;14(12):16698–16711. doi:10.1021/acsnano.0c03776
108. Wang D, Liu C, You S, et al. Bacterial vesicle-cancer cell hybrid
membrane-coated nanoparticles for tumor specific immune activa
tion and photothermal therapy. ACS Appl Mater Interfaces. 2020;12
(37):41138–41147. doi:10.1021/acsami.0c13169
109. Kulp A, Kuehn MJ. Biological functions and biogenesis of secreted
bacterial outer membrane vesicles. Annu Rev Microbiol. 2010;64
(1):163–184. doi:10.1146/annurev.micro.091208.073413
110. Chen Q, Bai H, Wu W, et al. Bioengineering bacterial
vesicle-coated polymeric nanomedicine for enhanced cancer
immunotherapy and metastasis prevention. Nano Lett. 2020;20
(1):11–21. doi:10.1021/acs.nanolett.9b02182
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