Mathematical model of cooperative work of ion pump,symport and antiport in epithelial cells

Transcellular transport in epithelial cells plays an important role in providing such physiological functions as excretion of cytotoxic substances or reabsorption of metabolites useful for the body life activity. These functions have been shown to be performed by the mechanisms—symport, antiport, ion pumps, and channels—that often function cooperatively. Models for kinetic peculiarities of the substrate transport with the aid of the above mechanisms are widely described in the literature. Much less attention is paid to modeling of cooperative activity of transporters that have different transport mechanisms. In this work we propose a mathematical model for flux coupling of three transporters—the ion pump, symporter, and antiporter as well as of two substrates, one of which (A) can be transported simultaneously by the symport and antiport mechanisms, while the other (B)—only by the latter mechanism. Analysis of the model has shown that for the pair of substrates (A and B) the flux coupling becomes possible if the following conditions are met: (1) the substrate A flux into the internal cell volume using the symport mechanism is to exceed its antiporter-realized flux in the opposite direction; (2) probability of reorientation from one side of membrane to the other side for the antiporter loaded with the substrate is to be essentially higher than that for empty transporter. The proposed model can be used for comparing efficiency both of excretion and of reabsorption of cell metabolites in representatives of different taxa.     

Coupling of Na<Superscript>+</Superscript>/α-ketoglutarate symport and PAH/α-ketoglutarate antiport in epithelial cells. Estimation of probability of the anion exchanger spontaneous re-orientation

In this work, dynamics was studied of uptake of p-aminohippurate by basolateral membrane vesicles isolated from rat kidney proximal tubules. The uphill PAH transport into the basolateral membrane vesicles was shown to occur in the presence of α-ketoglutarate and Na⁺-gradient. Based on mathematical model of symport and antiport cooperation, the mechanism of energy coupling of PAH transport via exchanger with Na⁺-dicarboxylate symport is discussed. Based on comparison of our own and literature data, the data analysis shows adequacy of the proposed mathematical model to describe the symport and antiport cooperation. This model has been shown to enable estimation of re-orientation probability of the empty anion exchanger (without substrate) from one membrane side to the other.     

Transport of C(4)-dicarboxylates in Wolinella succinogenes

C(4)-dicarboxylate transport is a prerequisite for anaerobic respiration with fumarate in Wolinella succinogenes, since the substrate site of fumarate reductase is oriented towards the cytoplasmic side of the membrane. W. succinogenes was found to transport C(4)-dicarboxylates (fumarate, succinate, malate, and aspartate) across the cytoplasmic membrane by antiport and uniport mechanisms. The electrogenic uniport resulted in dicarboxylate accumulation driven by anaerobic respiration. The molar ratio of internal to external dicarboxylate concentration was up to 10(3). The dicarboxylate antiport was either electrogenic or electroneutral. The electroneutral antiport required the presence of internal Na(+), whereas the electrogenic antiport also operated in the absence of Na(+). In the absence of Na(+), no electrochemical proton potential (delta p) was measured across the membrane of cells catalyzing fumarate respiration. This suggests that the proton potential generated by fumarate respiration is dissipated by the concomitant electrogenic dicarboxylate antiport. Three gene loci (dcuA, dcuB, and dctPQM) encoding putative C(4)-dicarboxylate transporters were identified on the genome of W. succinogenes. The predicted gene products of dcuA and dcuB are similar to the Dcu transporters that are involved in the fumarate respiration of Escherichia coli with external C(4)-dicarboxylates. The genes dctP, -Q, and -M probably encode a binding-protein-dependent secondary uptake transporter for dicarboxylates. A mutant (DcuA(-) DcuB(-)) of W. succinogenes lacking the intact dcuA and dcuB genes grew by nitrate respiration with succinate as the carbon source but did not grow by fumarate respiration with fumarate, malate, or aspartate as substrates. The DcuA(-), DcuB(-), and DctQM(-) mutants grew by fumarate respiration as well as by nitrate respiration with succinate as the carbon source. Cells of the DcuA(-) DcuB(-) mutant performed fumarate respiration without generating a proton potential even in the presence of Na(+). This explains why the DcuA(-) DcuB(-) mutant does not grow by fumarate respiration. Growth by fumarate respiration appears to depend on the function of the Na(+)-dependent, electroneutral dicarboxylate antiport which is catalyzed exclusively by the Dcu transporters. Dicarboxylate transport via the electrogenic uniport is probably catalyzed by the DctPQM transporter and by a fourth, unknown transporter that may also operate as an electrogenic antiporter.     

Role of N-linked oligosaccharides in the transport activity of the Na+/H+ antiporter in rat renal brush-border membrane

The role of N-linked oligosaccharide side chains in the biogenesis and function of Na+-coupled transporters in renal luminal brush-border membrane (BBM) is not known. We examined the question of how in vivo inhibition by alkaloid swainsonine of alpha-mannosidase, a key enzyme in processing of glycoproteins in the Golgi apparatus, affects Na+/H+ antiport and Na+/Pi symport as well as activities of other transporters and enzymes in rat renal BBM. Administration of swainsonine to thyroparathyroidectomized rats, control or treated with 3,5,3'-triiodothyronine, markedly decreased the rate of Na+/H+ antiport, but had no effect on the rate of Na+/Pi symport across renal BBM vesicles (BBMV). Moreover, administration of swainsonine did not change activities of Na+ gradient, ([extravesicular Na+] greater than [intravesicular Na+])-dependent transport of D-glucose, L-proline, or the amiloride-insensitive 22Na+ uptake by BBMV; the activities of the BBM enzymes alkaline phosphatase, gamma-glutamyltransferase, or leucine aminopeptidase in BBMV were also not changed. The in vitro enzymatic deglycosylation of BBM by incubating freshly isolated BBMV with bacterial endoglycosidase F also resulted in a decreased rate of Na+/H+ antiport, but not Na+-coupled symports of Pi, L-proline, and D-glucose, or the activities of the BBM enzymes were not significantly affected. Similar incubation with endoglycosidase H was without effect on any of these parameters. Both the modification of BBMV glycoproteins by administration fo swainsonine in vivo as well as the in vitro incubation of BBMV with endoglycosidase F resulted in a decrease of the apparent Vmax of Na+/H+ antiport, but did not change the apparent Km of this antiporter for extravesicular Na+ and did not increase H+ conductance of BBM. Taken together, our findings suggest that intact N-linked oligosaccharide chains of the biantennary complex type in renal BBM glycoproteins are required, directly or indirectly, for the transport function of the Na+/H+ antiporter inserted into BBM of renal proximal tubules.     

Variety of nucleotide sugar transporters with respect to the interaction with nucleoside mono- and diphosphates

Nucleotide sugar transporters have long been assumed to be antiporters that exclusively use nucleoside monophosphates as antiport substrates. Here we present evidence indicating that two other types of nucleotide sugar transporters exist that differ in their antiport substrate specificity. Biochemical studies using microsomes derived from Saccharomyces cerevisiae cells expressing either human (h) UGTrel7 or the Drosophila (d) FRC (Fringe connection) transporter revealed that (i) efflux of preloaded UDP-glucuronic acid from the yeast microsomes expressing hUGTrel7 was strongly enhanced by UDP-GlcNAc added in the external medium, but not by UMP or UDP, suggesting that hUGTrel7 may be described as a UDP-sugar/UDP-sugar antiporter, and (ii) addition of UDP-sugars, UDP, or UMP in the external medium stimulated the efflux of preloaded UDP-GlcNAc from the yeast microsomes expressing dFRC to a comparable extent, suggesting that UDP, as well as UMP, may serve as an antiport substrate of dFRC. Antiport of UDP-sugars with these specific substrates was reproduced and definitively confirmed using proteoliposomes reconstituted from solubilized and purified transporters. Possible physiological implications of these observations are discussed.     

Cell free expression and functional reconstitution of eukaryotic drug transporters

Polyspecific organic cation and anion transporters of the SLC22 protein family are critically involved in absorption and excretion of drugs. To elucidate transport mechanisms, functional and biophysical characterization of purified transporters is required and tertiary structures must be determined. Here, we synthesized rat organic cation transporters OCT1 and OCT2 and rat organic anion transporter OAT1 in a cell free system in the absence of detergent. We solubilized the precipitates with 2% 1-myristoyl-2-hydroxy- sn-glycero-3-[phospho- rac-(1-glycerol)] (LMPG), purified the transporters in the presence of 1% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) or octyl glucoside, and reconstituted them into proteoliposomes. From 1 mL reaction vessels 0.13-0.36 mg of transporter proteins was purified. Thus, from five to ten 1 mL reaction vessels sufficient protein for crystallization was obtained. In the presence of 1% LMPG and 0.5% CHAPS, OCT1 and OAT1 formed homo-oligomers but no hetero-oligomers. After reconstitution of OCT1, OCT2, and OAT1 into proteoliposomes, similar Michaelis-Menten K m values were measured for uptake of 1-methyl-4-phenylpyridinium and p-aminohippurate (PAH (-)) by the organic cation and anion transporters, respectively, as after expression of the transporters in cells. Using the reconstituted system, evidence was obtained that OAT1 operates as obligatory and electroneutral PAH (-)/dicarboxylate antiporter and contains a low-affinity chloride binding site that stimulates turnover. PAH (-) uptake was observed only with alpha-ketoglutarate (KG (2-)) on the trans side, and trans-KG (2-) increased the PAH (-) concentration in voltage-clamped proteoliposomes transiently above equilibrium. The V max of PAH (-)/KG (2-) antiport was increased by Cl (-) in a manner independent of gradients, and PAH (-)/KG (2-) antiport was independent of membrane potential in the absence or presence of Cl (-).     

Pore-like and carrier-like properties of the mitochondrial aspartate/glutamate carrier after modification by SH-reagents: evidence for a performed channel as a structural requirement of carrier-mediated transport.

Upon modification of the reconstituted aspartate/glutamate carrier by mercury reagents the antiporter was converted into a unidirectional efflux carrier (Dierks, T., Salentin, A., Heberger, C. and Kr?mer, R. (1990) Biochim. Biophys. Acta 1028, 268). In addition to this basic change in the mechanism, the mercurials, reacting with exofacial cysteines, also affected the internal binding site of the carrier leading to an unmeasurable high Km and to a drastically reduced substrate specificity. The spectrum of efflux substrates comprised small anions from chloride to glutamate, but not cationic amino acids and ATP, hence resembling pore-like properties. However, in the efflux state important carrier properties were also observed. The activation energy (86 kJ/mol) was as high as for the antiport. Furthermore, efflux was inhibited by the presence of external substrate. This trans-inhibition strongly suggests that the external binding site of the carrier, prerequisite in the antiport mechanism, also is involved in conformational transitions during efflux function. However, antiport no longer is catalyzed after switching to the efflux state. Reversion of the induced efflux carrier to the antiport state was achieved using dithioerythritol, thereby further restoring substrate specificity and saturation kinetics. A model for antiport-efflux interconversion is presented suggesting that two reactive cysteines have to be modified in order to uncouple the inward and outward directed component of antiport. The pore-type characteristics of efflux are taken as evidence that a channel-like structure determines the selectivity of unidirectional transport. This intrinsic channel of the protein then is required for substrate translocation also during antiport function.     

Chloride ATPase pumps in nature: do they exist?

Five widely documented mechanisms for chloride transport across biological membranes are known: anion-coupled antiport, Na+ and H(+)-coupled symport, Cl- channels and an electrochemical coupling process. These transport processes for chloride are either secondarily active or are driven by the electrochemical gradient for chloride. Until recently, the evidence in favour of a primary active transport mechanism for chloride has been inconclusive despite numerous reports of cellular Cl(-)-stimulated ATPases coexisting, in the same tissue, with uphill ATP-dependent chloride transport. Cl(-)-stimulated ATPase activity is a ubiquitous property of practically all cells with the major location being of mitochondrial origin. It also appears that plasma membranes are sites of Cl(-)-stimulated ATPase pump activity. Recent studies of Cl(-) -stimulated ATPase activity and ATP-dependent chloride transport in the same plasma membrane system, including liposomes, strongly suggest a mediation by the ATPase in the net movement of chloride up its electrochemical gradient across the plasma membrane structure. Contemporary evidence points to the existence of Cl(-)-ATPase pumps; however, these primary active transporters exist as either P-, F- or V-type ATPase pumps depending upon the tissue under study.     

Mechanisms of drug/H+ antiport: complete cysteine-scanning mutagenesis and the protein engineering approach

The notorious difficulty of elucidating structures of membrane transporters by crystallography has long prevented our understanding of active transport mechanism coupled with ion/proton transport. The determination of the first crystal structure of the drug/H+ antiporter AcrB was a breakthrough for structure-based understanding of drug/H+ antiport. However, although AcrB is a major multidrug exporter in Gram-negative organisms, the majority of bacterial drug exporters are major facilitator superfamily (MFS) drug transporters. As no crystal structures have been solved for MFS transporters, the alternative protein-engineering methods are still very useful for estimating structures and functions of drug/H+ antiporters. This review describes this alternative approach for investigating the structure and function of tetracycline/H+ antiporters.     

Single-file diffusion and neurotransmitter transporters: Hodgkin and Keynes model revisited

Norepinephrine transporters (NETs) use the Na gradient to remove norepinephrine (NE) from the synaptic cleft of adrenergic neurons following NE release from the presynaptic terminal. By coupling NE to the inwardly directed Na gradient, it is possible to concentrate NE inside cells. This mechanism, which is referred to as co-transport or secondary transport (L?uger, 1991, Electrogenic Ion Pumps, Sinauer Associates) is apparently universal: Na coupled transport applies to serotonin transporters (SERTs), dopamine transporters (DATs), glutamate transporters, and many others, including transporters for osmolites, metabolites and substrates such as sugar. Recently we have shown that NETs and SERTs transport norepinephrine or serotonin as if Na and the transmitter permeated through an ion channel together 'Galli et al., 1998, PNAS 95, 13260-13265; Petersen and DeFelice, 1999, Nature Neurosci. 2, 605-610'. These data are paradoxical because it has been difficult to envisage how NE, for example, would couple to Na if these ions move passively through an open pore. An 'alternating access' model is usually evoked to explain coupling: in such models NE and Na bind to NET, which then undergoes a conformational change to release NE and Na on the inside. The empty transporter then turns outward to complete the cycle. Alternating-access models never afford access to an open channel. Rather, substrates and co-transported ions are occluded in the transporter and carried across the membrane. The coupling mechanism we propose is fundamentally different than the coupling mechanism evoked in the alternating access model. To explain coupling in co-transporters, we use a mechanism first evoked by 'Hodgkin and Keynes (1955) J. Physiol. 128, 61-88' to explain ion interactions in K-selective channels. In the Hodgkin and Keynes model, K ions move single-file through a long narrow pore. Their model accounted for the inward/outward flux ratio if they assumed that two K ions queue within the pore. We evoke a similar model for the co-transport of transmitter and Na. In our case, however, coupling occurs not only between like ions but also between unlike ions (i.e. the transmitter and Na ). We made a replica of the Hodgkin and Keynes mechanical model to test our ideas, and we extended the model with computer simulations using Monte Carlo methods. We also developed an analytic formula for Na coupled co-transport that is analogous to the single-file Ussing equation for channels. The model shows that stochastic diffusion through a long narrow pore can explain coupled transport. The length of the pore amplifies the Na gradient that drives co-transport.     

Proposed partial beta-structures for lac permease and the Na+/H+ antiporter which use similar transport and H+ coupling mechanisms.

Most antiporters, symporters, and transporters have been represented as containing ten to 14 transmembrane helices, primarily on the basis of hydropathy plots. However, multihelix systems provide no obvious mechanism of transport and no simple way of distinguishing substrates. The models of lac permease and the Na+/H+ antiporter presented here postulate that beta-structures are involved in the transport of substrate, and in following this postulate arrive at readily understandable mechanisms for transport and for substrate specificity. The percentage of beta-structures necessary for these models is low enough that it is not in conflict with prior physical evidence for secondary structures. Immunological data also cannot rule these beta-structure mechanisms invalid. In lac permease the new model is obtained by formal representation of the C-terminal amino acids 243-405 as beta-strands. This formal representation nets two interchangeable beta-barrels which provide a simple mechanism for sugar transport. The alternating barrel system may comprise as little as 1/5 the entire permease. In one configuration the barrel forms a pocket with hydrogen bonding residues oriented to the outside of the cell. In the other configuration the barrel forms an analogous pocket oriented towards the inside. Six particular amino acids participate in the substrate hydrogen bonding schemes of both forms, providing a mechanism to shuttle lactose from the outside to the inside or vice versa. A trigger for change of forms which could couple the beta-barrel to H(+)-transport is easily devised, and it involves the apparently critical His322-Glu325 charge relay system. The Na+/H+ antiporter can be organized similarly with an interchanging beta-barrel-beta-clamshell structure attached to 7-transmembrane helices. Charged amino acid sidechains form the basis of an ionic shuttle which is analogous to the lactose shuttle. In this case, too, coupling of Na+ transport to H+ transport may be accomplished by a histidine-glutamate charge relay system.     

Flavone glucoside uptake into barley mesophyll and Arabidopsis cell culture vacuoles. Energization occurs by H(+)-antiport and ATP-binding cassette-type mechanisms

In many cases, secondary plant products accumulate in the large central vacuole of plant cells. However, the mechanisms involved in the transport of secondary compounds are only poorly understood. Here, we demonstrate that the transport mechanisms for the major barley (Hordeum vulgare) flavonoid saponarin (apigenin 6-C-glucosyl-7-O-glucoside) are different in various plant species: Uptake into barley vacuoles occurs via a proton antiport and is competitively inhibited by isovitexin (apigenin 6-C-glucoside), suggesting that both flavone glucosides are recognized by the same transporter. In contrast, the transport into vacuoles from Arabidopsis, which does not synthesize flavone glucosides, displays typical characteristics of ATP-binding cassette transporters. Transport of saponarin into vacuoles of both the species is saturable with a K(m) of 50 to 100 microM. Furthermore, the uptake of saponarin into vacuoles from a barley mutant exhibiting a strongly reduced flavone glucoside biosynthesis is drastically decreased when compared with the parent variety. Thus, the barley vacuolar flavone glucoside/H(+) antiporter could be modulated by the availability of the substrate. We propose that different vacuolar transporters may be responsible for the sequestration of species-specific/endogenous and nonspecific/xenobiotic secondary compounds in planta.     

Evolutionary ancestry and novel functions of the mammalian glucose transporter (GLUT) family

Background  

In general, sugar porters function by proton-coupled symport or facilitative transport modes. Symporters, coupled to electrochemical energy, transport nutrients against a substrate gradient. Facilitative carriers transport sugars along a concentration gradient, thus transport is dependent upon extracellular nutrient levels. Across bacteria, fungi, unicellular non-vertebrates and plants, proton-coupled hexose symport is a crucial process supplying energy under conditions of nutrient flux. In mammals it has been assumed that evolution of whole body regulatory mechanisms would eliminate this need. To determine whether any isoforms bearing this function might be conserved in mammals, we investigated the relationship between the transporters of animals and the proton-coupled hexose symporters found in other species.     

Secondary active transport

Secondary active transport is defined as the transport of a solute in the direction of its increasing electrochemical potential coupled to the facilitated diffusion of a second solute (usually an ion) in the direction of its decreasing electrochemical potential. The coupling agents are membrane proteins (carriers), each of which catalyzes simultaneously the facilitated diffusion of the driving ion and the active transport of a given solute. The review starts with some considerations on the energetics followed by a presentation of the kinetics of secondary active transport. Examples of information which may be gained by such studies are discussed. In the second part, some examples of secondary transport are given; we also describe the characteristics of the corresponding carriers. The various transport systems presented are: the D-glucose/Na+ symport in brush-border membranes, the lactose/H+ symport in E. coli, the Na+/H+ antiport, the different transport systems in the inner mitochondrial membrane.     

The structural basis of secondary active transport mechanisms

Secondary active transporters couple the free energy of the electrochemical potential of one solute to the transmembrane movement of another. As a basic mechanistic explanation for their transport function the model of alternating access was put forward more than 40 years ago, and has been supported by numerous kinetic, biochemical and biophysical studies. According to this model, the transporter exposes its substrate binding site(s) to one side of the membrane or the other during transport catalysis, requiring a substantial conformational change of the carrier protein. In the light of recent structural data for a number of secondary transport proteins, we analyze the model of alternating access in more detail, and correlate it with specific structural and chemical properties of the transporters, such as their assignment to different functional states in the catalytic cycle of the respective transporter, the definition of substrate binding sites, the type of movement of the central part of the carrier harboring the substrate binding site, as well as the impact of symmetry on fold-specific conformational changes. Besides mediating the transmembrane movement of solutes, the mechanism of secondary carriers inherently involves a mechanistic coupling of substrate flux to the electrochemical potential of co-substrate ions or solutes. Mainly because of limitations in resolution of available transporter structures, this important aspect of secondary transport cannot yet be substantiated by structural data to the same extent as the conformational change aspect. We summarize the concepts of coupling in secondary transport and discuss them in the context of the available evidence for ion binding to specific sites and the impact of the ions on the conformational state of the carrier protein, which together lead to mechanistic models for coupling.     

Role of Transmembrane Domain 8 in Substrate Selectivity and Translocation of SteT,a Member of the l-Amino Acid Transporter (LAT) Family

System l-amino acid transporters (LAT) belong to the amino acid, polyamine, and organic cation superfamily of transporters and include the light subunits of heteromeric amino acid transporters and prokaryotic homologues. Cysteine reactivity of SteT (serine/threonine antiporter) has been used here to study the substrate-binding site of LAT transporters. Residue Cys-291, in transmembrane domain 8 (TM8), is inactivated by thiol reagents in a substrate protectable manner. Surprisingly, DTT activated the transporter by reducing residue Cys-291. Cysteine-scanning mutagenesis of TM8 showed DTT activation in the single-cysteine mutants S287C, G294C, and S298C, lining the same α-helical face. S-Thiolation in Escherichia coli cells resulted in complete inactivation of the single-cysteine mutant G294C. l-Serine blocked DTT activation with an EC₅₀ similar to the apparent K_M of this mutant. Thus, S-thiolation abolished substrate translocation but not substrate binding. Mutation of Lys-295, to Cys (K295C) broadened the profile of inhibitors and the spectrum of substrates with the exception of imino acids. A structural model of SteT based on the structural homologue AdiC (arginine/agmatine antiporter) positions residues Cys-291 and Lys-295 in the putative substrate binding pocket. All this suggests that Lys-295 is a main determinant in the recognition of the side chain of SteT substrates. In contrast, Gly-294 is not facing the surface, suggesting conformational changes involving TM8 during the transport cycle. Our results suggest that TM8 sculpts the substrate-binding site and undergoes conformational changes during the transport cycle of SteT.     

Proton-driven sucrose symport and antiport are provided by the vacuolar transporters SUC4 and TMT1/2

The vacuolar membrane is involved in solute uptake into and release from the vacuole, which is the largest plant organelle. In addition to inorganic ions and metabolites, large quantities of protons and sugars are shuttled across this membrane. Current models suggest that the proton gradient across the membrane drives the accumulation and/or release of sugars. Recent studies have associated AtSUC4 with the vacuolar membrane. Some members of the SUC family are plasma membrane proton/sucrose symporters. In addition, the sugar transporters TMT1 and TMT2, which are localized to the vacuolar membrane, have been suggested to function in proton-driven glucose antiport. Here we used the patch-clamp technique to monitor carrier-mediated sucrose transport by AtSUC4 and AtTMTs in intact Arabidopsis thaliana mesophyll vacuoles. In the whole-vacuole configuration with wild-type material, cytosolic sucrose-induced proton currents were associated with a proton/sucrose antiport mechanism. To identify the related transporter on one hand, and to enable the recording of symporter-mediated currents on the other hand, we electrophysiologically characterized vacuolar proteins recognized by Arabidopsis mutants of partially impaired sugar compartmentation. To our surprise, the intrinsic sucrose/proton antiporter activity was greatly reduced when vacuoles were isolated from plants lacking the monosaccharide transporter AtTMT1/TMT2. Transient expression of AtSUC4 in this mutant background resulted in proton/sucrose symport activity. From these studies, we conclude that, in the natural environment within the Arabidopsis cell, AtSUC4 most likely catalyses proton-coupled sucrose export from the vacuole. However, TMT1/2 probably represents a proton-coupled antiporter capable of high-capacity loading of glucose and sucrose into the vacuole.     

Molecular characteristics of transporters of C<Subscript>4</Subscript>-dicarboxylates and mechanism of translocation

An important role in cell metabolism is played by transport of C₄-dicarboxylates (C₄-DCB). Specifically, they are intermediates of the citrate cycle. Transport of succinate across the mitochondrial membrane provides correlation between metabolism in peroxysomes and in mitochondria. There is known transport of C₄-DCB across all kinds of energy-transforming membranes of the animal, plant, fungal, and bacterial cells. This review summarizes molecular characteristics of the C₄-DCB transporters. Of particular interest are primary structures for the transporters with the known kinetic mechanism and kinetic transport parameters. For each studied group of organisms, the number of transmembrane segments in the carried molecule or the character of specificity does not correlate with the certain transport mechanism—antiport, symport with proton or symport with cation. The review describes perspective methodical approaches allowing association of peculiarities of structure with transport mechanism for individual transporters, preparation of functional hybrid transporters—“protein chimeras,” scanning of transporter transmembrane segments with aid of essential acids, probing of the transporter active center with aid of alkyl and acyl substrate derivatives used to obtain the “lipophilic profile” of the channel of the C₄-DCB transporter. It is recommended to use these approaches to one transporter that has small sizes and large substrate specificity.