Technical articles

Bacterial Sodium Ion-Driven Energy Metabolism and Mechanisms of Transmembrane Coupled Transport

Membrane energy transduction in bacteria does not rely exclusively on the proton motive force. In marine bacteria, alkaliphiles, certain anaerobes, and a number of environmentally adaptive Gram-negative bacteria, Na+ serves not only as an important carrier of transmembrane electrochemical potential, but also as a directly coupled ion for nutrient uptake, ion exchange, drug efflux, and flagellar motility. Rather than being viewed simply as a supplement to proton-based systems, the Na+-driven network possesses a relatively independent logic of generation, conversion, and utilization. The relationships among establishment of the sodium gradient, membrane-energy allocation, transmembrane coupled transport, and cellular physiological output have therefore become an important direction in bacterial ion bioenergetics.

 

Keywords: sodium motive force; Na+-NQR; Na+/H+ antiporter; TRAP transporter; MATE efflux pump; oxaloacetate decarboxylase; flagellar motor; transmembrane coupling

 

1. Basic Framework of Sodium Ion Energy Metabolism

1.1 Metabolic significance of Na+ as a membrane-energy carrier

(1) The Na+ gradient is an independently usable transmembrane electrochemical potential

The distribution of Na+ across the bacterial membrane is not a passive equilibrium outcome, but can be actively established as a stable transmembrane electrochemical gradient through active export. Similar to the proton motive force, the sodium motive force consists of a membrane-potential component and a Na+ chemical potential difference, and it is capable of driving substrate transport, ion exchange, ATP synthesis, and mechanical motion. Thus, Na+ is not merely an accompanying ion, but a functional carrier in membrane-energy economy.


(2) Sodium ion systems are better suited to certain specific ecological conditions

Under conditions of high salinity, limited proton availability, or alkaline environments, exclusive reliance on an H+ gradient often faces increased leakage, reduced coupling efficiency, and restricted proton availability at the membrane surface. By contrast, Na+ generally shows a lower tendency for spontaneous transmembrane backflow and can therefore maintain a usable gradient more effectively under certain conditions. Accordingly, sodium-driven modules are especially common in marine bacteria, alkaliphiles, and some facultative anaerobes.

 

1.2 Relationship between sodium ion systems and proton systems

(1) The two systems are not mutually exclusive, but operate in parallel and through interconversion

Most bacteria do not "use only Na+" or "use only H+." Instead, sodium ion systems and proton systems are deployed simultaneously at different levels. Certain respiratory-chain modules and antiporters can also mediate interconversion between the two motive-force systems. Sodium ion metabolism should therefore be regarded as an important branch within the membrane-energy network rather than as an isolated special mechanism.


(2) The Na+ system often fulfills a condition-adaptive role

In many bacterial species, the H+ system remains the basic energy module, whereas the Na+ system is strengthened under high-salt conditions, alkaline stress, low proton availability, or specific substrate-metabolism conditions. In other words, the sodium ion system often represents a condition-adaptive mode of membrane-energy utilization rather than a mere accessory structure of the conventional respiratory chain.

 

2. Mechanisms for Establishment of the Sodium Ion Gradient

2.1 Respiration-related sodium pumps

(1) Na+-NQR constitutes a typical primary sodium pump

The Na+-translocating NADH:quinone oxidoreductase couples NADH oxidation to Na+ extrusion and is a representative primary module for establishment of the sodium motive force. The significance of this complex lies not only in electron transfer, but also in its direct conversion of reducing power into a transmembrane Na+ potential.

(2) The RNF complex reflects coupling between reducing-power organization and Na+ extrusion

In certain anaerobes and acetogenic bacteria, the RNF complex couples electron transfer between ferredoxin and NAD+ to transmembrane Na+ transport. This indicates that the sodium motive force can be generated not only by the classical respiratory chain, but also within the framework of anaerobic reducing-power redistribution.

 

2.2 Sodium pumps driven by decarboxylation reactions

(1) Decarboxylation reactions can be directly converted into transmembrane Na+ driving force

Certain biotin-dependent decarboxylase complexes, such as oxaloacetate decarboxylase and methylmalonyl-CoA decarboxylase, can couple the free energy released by decarboxylation to Na+ export. These systems demonstrate that the sodium motive force does not rely exclusively on the respiratory chain, but can also be established directly by intermediate-metabolic reactions.

(2) Oxaloacetate decarboxylase exemplifies coupling between metabolic nodes and membrane-energy conversion

Oxaloacetate decarboxylase participates not only in central-metabolic carbon-flux partitioning, but can also function as a sodium-pump module. This means that certain metabolic enzymes are not merely nodes of intermediate metabolism, but also membrane-energy-generating devices. Therefore, sodium ion energy metabolism cannot be discussed as entirely separate from core metabolism.

 

2.3 ATP synthase and reverse-coupling modules

(1) ATP synthase in some bacteria can directly utilize the Na+ gradient

In certain bacteria, the F-type ATP synthase does not rely solely on H+ as the driving ion, but can directly use Na+ backflow to accomplish ATP synthesis. This indicates that the Na+ gradient serves not only transport, but can also directly enter the level of chemical-energy generation.

(2) ATP synthase may function as a bidirectional coupling device under different conditions

When the transmembrane Na+ potential is sufficiently strong, ATP synthase can be used for ATP production. Under certain reverse conditions, it may also participate in reconstruction of ion gradients through ATP hydrolysis. Thus, in sodium ion systems, ATP synthase is not merely a terminal utilization module, but may also participate in membrane-energy redistribution.


Table 1. Modules for establishment of the sodium motive force and their metabolic significance

 

Module

Representative System

Major Coupled Reaction

Metabolic Significance

Respiratory sodium pump

Na+-NQR

NADH oxidation coupled to Na+ extrusion

Establishes the primary sodium motive force and links the respiratory chain to membrane-energy conversion

Reducing-power-coupling module

RNF complex

Ferredoxin/NAD+ interconversion coupled to Na+ extrusion

Converts anaerobic reducing-power redistribution into a transmembrane Na+ potential

Decarboxylation-type sodium pump

Oxaloacetate decarboxylase and related systems

Decarboxylation coupled to Na+ extrusion

Directly converts free energy from intermediate metabolism into membrane energy

Sodium-type ATP synthase

Na+-dependent F-type ATP synthase

Na+ backflow coupled to ATP synthesis

Converts the sodium motive force into ATP

Motive-force conversion module

Na+/H+ antiporter

Exchange of Na+ and H+

Connects Na+-based and H+-based systems and regulates membrane-energy distribution

 

3. Directions of Utilization of the Sodium Motive Force

3.1 Nutrient uptake

(1) Na+-coupled transport is the most common mode of utilization of the sodium motive force

The uptake of many organic acids, amino acids, and other substrates can be directly coupled to Na+ influx. The essence of this process is the use of free energy released by Na+ movement down its electrochemical gradient to drive substrate import against its concentration gradient.

(2) High-affinity uptake often depends on Na+-driven modules

Under low-nutrient conditions, certain high-affinity transport systems depend more strongly on the sodium gradient to maintain sustained uptake capacity. Their significance lies not merely in "faster transport," but in allowing cells to maintain effective uptake even when substrate concentrations are low.

 

3.2 pH homeostasis and ion balance

(1) Na+/H+ antiporters are core homeostatic modules in sodium-based systems

Na+/H+ antiporters participate in intracellular pH regulation, buffering of salt load, and membrane-energy conversion by exchanging Na+ and H+. In alkaliphiles and halotolerant bacteria, these systems help both to reduce intracellular Na+ accumulation and to maintain proton availability.

(2) The Mrp complex reflects a multisubunit coupling feature

The Mrp-type Na+/H+ antiport system represents a solution for ion-homeostasis control under complex conditions. Its significance lies in demonstrating that sodium homeostasis is not always maintained by a single transporter, but may require coordinated coupling at the level of a multiprotein complex.

 

3.3 ATP synthesis, motility, and efflux

(1) Na+ can directly participate in ATP synthesis

In bacteria possessing sodium-type ATP synthase, Na+ backflow itself can be converted into the driving force for ATP synthesis. This elevates the Na+ gradient from an "auxiliary transport potential" to a "core energy-currency-generating potential."

(2) Na+ can also drive flagellar motors and drug efflux

The flagellar motors of some bacteria are driven by Na+ influx, and some MATE-family efflux pumps can use the Na+ gradient to export drugs or metabolic waste products. Accordingly, the sodium motive force serves not only uptake, but also motility and export.

 

4. Mechanistic Framework of Transmembrane Coupled Transport

4.1 Symport mechanisms

(1) Na+ and substrate cotransport reflects a logic of cooperative binding

In Na+-coupled symporters, Na+ and the substrate often stabilize a specific conformation through cooperative binding, after which the protein undergoes an alternating-access transition. The essence of this process is transfer of the free energy released by the ion gradient into conformational change, which then drives transmembrane substrate movement.

(2) Symport is especially suitable for enrichment of low-concentration substrates

Because the Na+ electrochemical potential is often strong, symporters are particularly suitable for substrate enrichment under low-concentration environmental conditions. Their mechanistic study typically focuses on Na+-binding sites, substrate specificity, and the sequence of conformational switching.

 

4.2 Antiport mechanisms

(1) Na+/H+ exchange reflects a mechanism of ion-potential interconversion

Antiporters achieve ion-homeostasis regulation and motive-force conversion by coupling the opposing movements of two ions. Such proteins do not primarily function in substrate uptake, but rather in control of intracellular Na+, regulation of intracellular pH, and reconstruction of membrane energy.

(2) Antiport can be either electroneutral or electrogenic

Different Na+/H+ antiporters differ in their ion stoichiometry. Some perform approximately electroneutral exchange, whereas others involve net charge transfer. Therefore, their functional consequences influence not only ion concentrations, but also the membrane-potential component.

 

4.3 Efflux and mechanical-coupling mechanisms

(1) MATE efflux pumps exemplify Na+-driven export mechanisms

Some members of the MATE family use the Na+ gradient to export drugs and toxic metabolic products. These systems demonstrate that the sodium gradient can support not only nutrient uptake, but also drug resistance and removal of metabolic waste.

(2) Sodium-driven flagellar motors exemplify conversion of ion flow into mechanical work

In sodium-driven flagellar systems, Na+ crosses the membrane through stator complexes, and the ion motive force is directly converted into rotational power of the rotor. This is one of the most direct examples of "ion potential to mechanical work" coupling in sodium ion energy metabolism.


Table 2. Major types of Na+-coupled transmembrane mechanisms

 

Coupling Type

Representative Apparatus

Main Function

Mechanistic Feature

Symport

TRAP transporters, SSS-family transporters

Substrate uptake

Na+ and substrate bind cooperatively and cross the membrane together

Antiport

Na+/H+ antiporters, Mrp complex

pH and salt homeostasis

Reshape Na+ and H+ potentials through ion exchange

Efflux coupling

MATE efflux pump

Export of drugs/metabolites

Uses Na+ or H+ gradient to drive efflux

Mechanical coupling

Na+-driven flagellar motor

Cellular motility

Directly converts Na+ flux into rotational force

Energy synthesis

Na+-type ATP synthase

ATP generation

Converts Na+ backflow into chemical energy

 

5. Physiological Adaptability of Sodium Ion Systems

5.1 Advantages in high-salt and alkaline environments

(1) Sodium ion systems support maintenance of membrane energy under conditions of limited proton availability

In alkaline environments, the availability of extracellular H+ declines, increasing the cost of relying exclusively on the proton motive force. Under such conditions, Na+-based systems can more readily maintain an effective transmembrane gradient, and are therefore often strengthened in alkaliphiles and marine bacteria.

(2) Sodium ion systems enhance hierarchical environmental adaptability

By simultaneously deploying H+-based and Na+-based systems, bacteria can switch or redistribute membrane-energy utilization strategies under different environmental conditions, thereby broadening their adaptive range. This "dual-ion strategy" is a major feature of bacterial ion bioenergetics.

 

5.2 Significance under anaerobic and specialized metabolic conditions

(1) Na+-based systems are often integrated with anaerobic reducing-power management

In certain anaerobes, Na+ extrusion can be driven by RNF or decarboxylation-type sodium pumps, making the sodium motive force highly coupled to reducing-power redistribution. Thus, sodium ion systems not only support membrane transport, but also participate in anaerobic energy conservation.

(2) Sodium ion modules favor recovery of free energy from low-energy reactions

Some decarboxylation reactions release only limited free energy. If this energy is dissipated directly, it is difficult to harness; when coupled to Na+ transport, however, part of it can be converted into storable transmembrane motive force. This reflects the particular value of sodium ion systems in low-energy metabolic reactions.

 

6. Research Strategies and Analytical Framework

6.1 Functional-assignment strategy

(1) The two levels of "generation of Na+ potential" and "utilization of Na+ potential" must be distinguished

In studies of sodium ion energy metabolism, one must first distinguish whether a given module is responsible for establishing the Na+ gradient or for utilizing it. Failure to distinguish these two roles can easily lead to misassignment of the physiological function of a protein.

(2) It is also necessary to distinguish "strictly Na+-specific systems" from "ion-switchable systems"

Some proteins are strictly dependent on Na+, whereas others can switch conditionally between Na+ and H+. Functional analysis therefore cannot rely only on phenotypes under a single ionic condition, but should combine ion substitution with perturbation of motive force.

 

6.2 Key priorities in mechanistic research

(1) Coupling stoichiometry and conformational change are central to mechanism

Whether in symport, antiport, or efflux, the key determinants of coupling efficiency are ion stoichiometry, binding order, and the pathway of conformational transition. Mechanistic studies should therefore focus on these core parameters rather than remaining at the level of merely showing that transport occurs.

(2) Reconstituted systems help separate complex background variables

In intact cells, Na+-based systems often coexist with H+-based systems, the respiratory chain, and multiple homeostatic modules. To define the function of a single module precisely, membrane-vesicle reconstitution, proteoliposome reconstruction, and experiments with controlled ion gradients usually provide stronger interpretive power.


Table 3. Major analytical dimensions in research on sodium ion energy metabolism

 

Analytical Dimension

Main Objects

Key Question Addressed

Gradient generation

Na+-NQR, RNF, decarboxylation-type sodium pumps

Where does the sodium motive force come from

Motive-force conversion

Na+/H+ antiporters

How are Na+ and H+ potentials interconverted

Transport coupling

TRAP, SSS, MATE, etc.

How does Na+ drive substrate uptake or efflux

Energy utilization

Na+-type ATP synthase, flagellar motor

How is the Na+ potential converted into ATP or mechanical work

Environmental adaptation

Marine bacteria, alkaliphiles, anaerobes

Why is the Na+ system strengthened under specific conditions

 

7. Research Products Related to Bacterial Sodium Ion Energy Metabolism and Transmembrane Coupled Transport


Table 4. Mechanistic probes and functional small molecules in studies of sodium-gradient establishment and transmembrane coupling

 

Name

CAS No.

Experimental Stage

Key Use

Use Notes

Monensin sodium salt

22373-78-0

Studies of Na+ gradient perturbation

Functions as a Na+ ionophore for dissipation or reconstruction of transmembrane Na+ distribution and analysis of Na+-motive-force-dependent processes

Suitable for validation of Na+-driven transport, efflux, and motility

Sodium Ionophore II

61595-77-5

Na+-selective perturbation studies

Used for selective regulation of transmembrane Na+ transport and Na+-responsive systems

Suitable for studies of Na+-specific electrochemical potential

Sodium Ionophore III

81686-22-8

Na+-selective detection/perturbation studies

Used in Na+-selective experimental systems and in analysis of Na+-transport responses

Suitable for construction of Na+-dependent transport and analytical methods

Valinomycin

2001-95-8

Membrane-potential control studies

Functions as a K+ ionophore for reconstruction or dissipation of membrane potential and for separating contributions of Δψ and ΔpNa

Suitable for potential-control experiments in Na+-coupled transport and flagellar-drive studies

Gramicidin A

11029-61-1

Membrane ion-permeability studies

Used to enhance transmembrane permeability to monovalent cations and evaluate membrane potential and ion-coupling processes

Suitable for membrane-energy perturbation and validation of transport coupling

Alamethicin

27061-78-5

Membrane channel-formation studies

Used as a monovalent-cation channel-forming molecule to analyze changes in membrane permeability

Suitable for membrane reconstitution and studies of ion-coupled permeability

CCCP

555-60-2

Studies distinguishing H+ and Na+ systems

Used as a classical protonophore to dissipate proton motive force and analyze whether Na+-based systems can independently sustain functional output

Suitable for distinguishing H+-driven from Na+-driven transport processes

FCCP

370-86-5

Proton-motive-force perturbation studies

Used for rapid dissipation of proton gradients and evaluation of the relative independence of Na+ modules within the membrane-energy network

Suitable for studies of Na+/H+ potential conversion and antiport

ATP Synthase Inhibitor 1

1023043-30-2

ATP-synthesis coupling studies

Used to analyze the relationship between the sodium motive force and ATP generation

Suitable for studies of Na+-type ATP synthase

Tetraphenylphosphonium bromide

2751-90-8

Studies of membrane-potential components

Used as a lipophilic cation probe for indirect analysis of membrane-potential changes

Suitable for distinguishing the membrane-potential component within the sodium motive force

Tetraphenylphosphonium iodide

2065-67-0

Studies of membrane-potential components

Used for membrane-potential-dependent accumulation analysis and comparison with alternative probes

Suitable for membrane-energy measurement under different detection systems

Tetraphenylphosphonium tetra-p-tolylborate

181259-35-8

Studies of membrane potential and hydrophobic ions

Used to construct lipophilic ion-migration models and analyze membrane-phase partitioning behavior

Suitable for optimization of hydrophobic-ion systems in membrane-potential studies

Sodium tetraphenylborate

143-66-8

Cation-migration auxiliary studies

Used to establish specific ion-migration conditions and assist analysis of transmembrane cation transfer behavior

Suitable for experimental design involving membrane-potential perturbation and ion selectivity

Ammonium tetraphenylborate

14637-34-4

Cation-migration auxiliary studies

Used together with tetraphenylborate-based systems to analyze ion behavior in membrane phases

Suitable for studies of ion transfer and membrane interfaces

Rhodamine 123

62669-70-9

Membrane-energy readout studies

Used as a fluorescence probe related to transmembrane potential to monitor changes in membrane-energy status

Suitable for comparing membrane-energy responses under different Na+ perturbation conditions

1,6-Diphenyl-1,3,5-hexatriene

484049-04-9

Membrane-fluidity studies

Used to analyze changes in membrane-lipid order and fluidity under ion-gradient perturbation

Suitable for studies of Na+ adaptation and membrane homeostasis

TMA-DPH

115534-33-3

Surface-membrane fluidity studies

Used to analyze changes in the membrane surface region after Na+ stress or ionophore treatment

Suitable for studies of bacterial membrane-surface fluidity and homeostasis

Amiloride hydrochloride dihydrate

17440-83-4

Na+-transport intervention studies

Used as a Na+-related transport probe to assess sensitivity of Na+-coupled exchange systems

More suitable for mechanistic discrimination than for direct use as a bacteria-specific inhibitor

EIPA

1154-25-2

Na+/H+ exchange studies

Used as an inhibitory probe for Na+/H+ exchange to analyze Na+/H+ antiport-related processes

Suitable for distinguishing the contribution of Na+/H+ exchange to membrane energy and pH homeostasis

Phenamil

2038-35-9

Na+-transport intervention studies

Used for mechanistic discrimination of Na+-flux-related processes

More suitable as an ion-transport probe than as a bacteria-specific effector molecule

Benzamil hydrochloride

161804-20-2

Na+-transport intervention studies

Used to analyze Na+-sensitive transport processes and ion-flux pathways

Suitable for validation of transport dependence and comparison of inhibitory sensitivity

Oxaloacetate

328-42-7

Studies of decarboxylation-type sodium pumps

Used to analyze coupling between oxaloacetate decarboxylase-related metabolism and Na+ extrusion

Suitable for validation of oxaloacetate decarboxylase function and substrate dependence

Succinic acid

110-15-6

Studies of Na+-coupled substrate uptake

Used as a representative C4 organic-acid substrate to analyze dicarboxylate uptake and its dependence on the Na+ gradient

Suitable for TRAP-related transport and organic-acid uptake studies

Fumaric acid

110-17-8

Studies of Na+-coupled substrate uptake

Used to analyze Na+-dependent uptake of dicarboxylate substrates and their metabolic connection

Suitable for studies of C4 substrate transport and transmembrane coupling

Citric acid

77-92-9

Studies of carboxylate-substrate transport

Used to analyze Na+-coupled uptake of polycarboxylate substrates and their metabolic adaptation

Suitable for studies of TRAP-type or carboxylate-uptake systems

L-Aspartic acid

56-84-8

Amino-acid transport studies

Used as an anionic amino-acid substrate to analyze Na+-dependent uptake processes

Suitable for studies of Na+-coupled amino-acid transport and selectivity

Norfloxacin

70458-96-7

MATE efflux studies

Used as a small-molecule efflux substrate to analyze function of Na+-coupled multidrug efflux systems

Suitable for evaluation of efflux-pump activity and inhibitory effects

Ethidium bromide

1239-45-8

MATE efflux and membrane-permeability studies

Used as a classical fluorescent efflux substrate to analyze efflux efficiency and changes in membrane integrity

Suitable for combined measurement of MATE-related efflux and membrane-energy perturbation

 

Table 5. Detection reagents and analytical products for studies of sodium ion energy metabolism and transmembrane coupled transport

 

Catalog No.

Name

Grade and Purity

Experimental Stage

Research Direction / Intended Use

I123841

Sodium Ion Selective Electrode Solutions

1000ppm Standard

Na+ quantitative analysis

Used to establish Na+ standard curves and calibrate electrode responses; suitable for determination of Na+ concentration in culture media, buffer systems, and ion-condition experiments

I123809

Sodium Ion Selective Electrode Solutions

ISA

Na+ quantitative analysis

Used to standardize ionic strength and stabilize measurement conditions in sodium ion-selective electrode systems; suitable for comparative studies of Na+ gradients

I123825

Sodium Ion Selective Electrode Solutions

0.1 M Standard

Na+ quantitative analysis

Used for standard calibration and validation under high-concentration conditions in Na+ electrode quantification; suitable for Na+-dependent growth and transport experiments

I123790

Sodium Ion Selective Electrode Solutions

Fill Solution

Na+ quantitative analysis

Used for maintenance and stable operation of sodium ion-selective electrode systems; suitable for continuous measurements and batch-sample analysis

R1375244

ATP Determination Kit

BioReagent,ready-to-use,for chemiluminescence

Energy-state studies

Used to detect changes in cellular ATP levels under different Na+ conditions or after ionophore treatment; suitable for analysis of the sodium motive force and energy-conservation efficiency

E1501756

Enhanced ATP Assay Kit

BioReagent

High-sensitivity ATP detection

Used for more sensitive detection of ATP changes after membrane-energy perturbation; suitable for low-abundance samples or short-term response experiments

E406176

E.coli / Yeast Protein Extraction Buffer

 

Protein-extraction analysis

Used for extraction of bacterial proteins and suitable for subsequent analysis of expression changes in Na+-NQR, Na+/H+ antiporters, and related membrane-energy modules

O1437367

Oxaloacetate decarboxylase

 

Decarboxylative sodium pump mechanism study

For mechanistic analysis of oxaloacetate decarboxylation, suitable for substrate dependence, Na+gradient perturbation, and reconstitution studies.

rp192098

Recombinant Human FAHD1/Oxaloacetate decarboxylase Protein

Carrier-free, His-tag, ≥95%(SDS-PAGE), see COA

Oxaloacetate decarboxylation enzymology study

For analysis of oxaloacetate decarboxylation activity and substrate conversion, suitable for in vitro enzymatic validation and metabolic mechanism studies.

 

The core of research on bacterial sodium ion energy metabolism lies in understanding how Na+ is transformed from an ordinary inorganic ion into a membrane-energy carrier that can be generated, converted, and utilized. Compared with frameworks that interpret bacterial membrane bioenergetics solely through proton-based systems, the sodium ion framework more effectively reveals the condition-adaptive strategies adopted by bacteria in saline, alkaline, and anaerobic environments.

 

For more related articles, please see below:

[1] Cellular Energy Metabolism Assay

[2] Quantitative Determination of ATP by Luminescence and Its Application in Cellular Energetics

Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

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Cite this article

Aladdin Scientific. "Bacterial Sodium Ion-Driven Energy Metabolism and Mechanisms of Transmembrane Coupled Transport" Aladdin Knowledge Base, updated Apr 7, 2026. https://www.aladdinsci.com/us_en/faqs/bacterial-sodium-ion-driven-energy-metabolism-and-mechanisms-of-transmembran-en.html
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