Lactate dehydrogenase in rat mitochondria

Small but persistent amounts of L-lactate dehydrogenase (LDH) activity were found in mitochondrial preparations isolated from rat heart, kidney, liver, and lymphocytes. Brain mitochondrial preparations were also isolated, but the results were inconclusive. A variety of cytosolic markers were used and it was found that essentially no cytosolic contamination was present except in brain preparations. A bacterial protease was used along with digitonin fractionation to determine localization of the mitochondrial LDH. Approximately 80% of the LDH activity associated with heart and kidney mitochondrial preparations was on the inside compared to about 40% for liver. Lymphocyte mitochondrial LDH activity was about 70% on the inside. Cytosolic LDH-5 preferentially adheres to outer mitochondrial membrane of liver, kidney, and heart. Agarose gel electrophoresis showed LDH isozymes in mitochondria qualitatively similar to that of the corresponding cytosol except in kidney mitochondrial preparations, where a specific electrophoretic band was found which did not correspond to any of the common LDH isozymes.     

L-lactate metabolism in potato tuber mitochondria

We investigated the metabolism of L-lactate in mitochondria isolated from potato tubers grown and saved after harvest in the absence of any chemical agents. Immunologic analysis by western blot using goat polyclonal anti-lactate dehydrogenase showed the existence of a mitochondrial lactate dehydrogenase, the activity of which could be measured photometrically only in mitochondria solubilized with Triton X-100. The addition of L-lactate to potato tuber mitochondria caused: (a) a minor reduction of intramitochondrial pyridine nucleotides, whose measured rate of change increased in the presence of the inhibitor of the alternative oxidase salicyl hydroxamic acid; (b) oxygen consumption not stimulated by ADP, but inhibited by salicyl hydroxamic acid; and (c) activation of the alternative oxidase as polarographically monitored in a manner prevented by oxamate, an L-lactate dehydrogenase inhibitor. Potato tuber mitochondria were shown to swell in isosmotic solutions of ammonium L-lactate in a stereospecific manner, thus showing that L-lactate enters mitochondria by a proton-compensated process. Externally added L-lactate caused the appearance of pyruvate outside mitochondria, thus contributing to the oxidation of extramitochondrial NADH. The rate of pyruvate efflux showed a sigmoidal dependence on L-lactate concentration and was inhibited by phenylsuccinate. Hence, potato tuber mitochondria possess a non-energy-competent L-lactate/pyruvate shuttle. We maintain, therefore, that mitochondrial metabolism of L-lactate plays a previously unsuspected role in the response of potato to hypoxic stress.     

Transport and metabolism of L-lactate occur in mitochondria from cerebellar granule cells and are modified in cells undergoing low potassium dependent apoptosis

Having confirmed that externally added L-lactate can enter cerebellar granule cells, we investigated whether and how L-lactate is metabolized by mitochondria from these cells under normal or apoptotic conditions. (1) L-lactate enters mitochondria, perhaps via an L-lactate/H+ symporter, and is oxidized in a manner stimulated by ADP. The existence of an L-lactate dehydrogenase, located in the inner mitochondrial compartment, was shown by immunological analysis. Neither the protein level nor the Km and Vmax values changed en route to apoptosis. (2) In both normal and apoptotic cell homogenates, externally added L-lactate caused reduction of the intramitochondrial pyridine cofactors, inhibited by phenylsuccinate. This process mirrored L-lactate uptake by mitochondria and occurred with a hyperbolic dependence on L-lactate concentrations. Pyruvate appeared outside mitochondria as a result of external addition of L-lactate. The rate of the process depended on L-lactate concentration and showed saturation characteristics. This shows the occurrence of an intracellular L-lactate/pyruvate shuttle, whose activity was limited by the putative L-lactate/pyruvate antiporter. Both the carriers were different from the monocarboxylate carrier. (3) L-lactate transport changed en route to apoptosis. Uptake increased in the early phase of apoptosis, but decreased in the late phase with characteristics of a non-competitive like inhibition. In contrast, the putative L-lactate/pyruvate antiport decreased en route to apoptosis with characteristics of a competitive like inhibition in early apoptosis, and a mixed non-competitive like inhibition in late apoptosis.     

Oxidation of cytosolic NADH by the malate-aspartate shuttle in HuH13 human hepatoma cells.

1. The reoxidation of cytosolic NADH was studied in a line of human hepatoma cells (HuH13) whose mitochondria preferentially utilized glutamine for ATP formation. 2. The tumor cells showed mitochondrial reoxidation of NADH, as evidenced by the accumulation of pyruvate, when incubated aerobically with L-lactate. The involvement of the respiratory chain was demonstrated by the addition of specific inhibitors. 3. Glutamine oxidation proceeded in the tumor mitochondria exclusively via a pathway involving transamination. Malate stimulated aspartate production from glutamine. 4. When the tumor cells were cultured in Eagle's medium with aminooxyacetate or in the absence of glutamine, a marked reduction in the cellular NAD/NADH ratio was observed. 5. These results indicate that the malate-aspartate shuttle was functioning in the tumor cells.     

Reinvestigation of the requirement of cytosolic ATP for mitochondrial protein import

Protein import into mitochondria requires the energy of ATP hydrolysis inside and/or outside mitochondria. Although the role of ATP in the mitochondrial matrix in mitochondrial protein import has been extensively studied, the role of ATP outside mitochondria (external ATP) remains only poorly characterized. Here we developed a protocol for depletion of external ATP without significantly reducing the import competence of precursor proteins synthesized in vitro with reticulocyte lysate. We tested the effects of external ATP on the import of various precursor proteins into isolated yeast mitochondria. We found that external ATP is required for maintenance of the import competence of mitochondrial precursor proteins but that, once they bind to mitochondria, the subsequent translocation of presequence-containing proteins, but not the ADP/ATP carrier, proceeds independently of external ATP. Because depletion of cytosolic Hsp70 led to a decrease in the import competence of mitochondrial precursor proteins, external ATP is likely utilized by cytosolic Hsp70. In contrast, the ADP/ATP carrier requires external ATP for efficient import into mitochondria even after binding to mitochondria, a situation that is only partly attributed to cytosolic Hsp70.     

Electron microscopic localization of lactate dehydrogenase in osteoclasts of chick embryo tibia

Synopsis Lactate dehydrogenase (LDH) was localized in osteoclasts of fixed and unfixed 19-day chick embryo tibias using a copper ferrocyanide capture reaction and osmiophilic polymer generation. This study revealed that: (1) LDH activity in fixed, briefly rinsed osteoclasts was associated principally with limiting membranes of cytoplasmic vacuoles and vesicles and with the plasma membrane; (2) LDH activity in unfixed osteoclasts was associated only with mitochondria; and (3) some mitochondria were stained in fixed tissue given a long rinse. These results indicate that: cytoplasmic LDH diffused out of unfixed tissue; mitochondrial LDH was inactivated by formaldehyde in fixed tissue; and formaldehyde-inhibited mitochondrial LDH can be reactivated by a long rinse. Although the vesicles that stained for LDH activity were found in all parts of the cell, they were concentrated near the ruffled border, and there is evidence that they contained material from the bone surface. These results suggest that the LDH associated with cytoplasmic vesicles of the osteoclast may be important in processing of material resorbed from the bone surface and that osteoclastic mitochondria may utilize lactate from the bone fluid for energy production.     

Ischemic preconditioning, insulin, and morphine all cause hexokinase redistribution

Association of hexokinase (HK) with mitochondria preserves mitochondrial integrity and is an important mechanism by which cancer cells are protected against hypoxic conditions. Maintenance of mitochondrial integrity also figures prominently as a major characteristic of many cardioprotective manipulations. In this study, we provide evidence that cardioprotective interventions may promote HK redistribution from the cytosol to the mitochondria in the heart. Isolated Langendorff-perfused rat hearts (n = 6/group) were subjected to normoxic perfusion (control, Con), three 5-min ischemia-reperfusion periods (ischemic preconditioning, IPC), 1 U/l insulin (Ins), or 1 microM morphine (Mor). Hearts were immediately homogenized and centrifuged to obtain whole cell, cytosolic, and mitochondrial fractions. HK, lactate dehydrogenase (LDH), and citrate synthase (CS) enzyme activities were determined. No change in LDH or CS present in the cytosol fraction relative to whole cell activity was observed with any of the cardioprotective interventions. By contrast, HK present in the cytosol fraction relative to whole cell activity decreased significantly (P < 0.05) with all cardioprotective interventions, from 0.58 +/- 0.03 (Con) to 0.46 +/- 0.04 (IPC), 0.41 +/- 0.01 (Ins), and 0.45 +/- 0.02 (Mor). In addition, HK relative to CS activity in the mitochondrial fraction increased significantly with cardioprotection, from 0.15 +/- 0.001 (Con) to 0.21 +/- 0.002 (IPC), 0.18 +/- 0.003 (Ins), and 0.21 +/- 0.005 (Mor). Our novel data suggest that well-known cardioprotective interventions share a common end-effector mechanism of cytosolic HK translocation. Association of HK with mitochondria may promote inhibition of the mitochondrial permeability transition pore and thereby reduce cell death and apoptosis.     

Electron Microscopic Analysis of a Spherical Mitochondrial Structure

Mitochondria undergo dynamic structural alterations to meet changing needs and to maintain homeostasis. We report here a novel mitochondrial structure. Conventional transmission electron microscopic examination of murine embryonic fibroblasts treated with carbonyl cyanide m-chlorophenylhydrazone (CCCP), a mitochondrial uncoupler, found that more than half of the mitochondria presented a ring-shaped or C-shaped morphology. Many of these mitochondria seemed to have engulfed various cytosolic components. Serial sections through individual mitochondria indicated that they formed a ball-like structure with an internal lumen surrounded by the membranes and containing cytosolic materials. Notably, the lumen was connected to the external cytoplasm through a small opening. Electron tomographic reconstruction of the mitochondrial spheroids demonstrated the membrane topology and confirmed the vesicular configuration of this mitochondrial structure. The outside periphery and the lumen were defined by the outer membranes, which were lined with the inner membranes. Matrix and cristae were retained but distributed unevenly with less being kept near the luminal opening. Mitochondrial spheroids seem to form in response to oxidative mitochondrial damage independently of mitophagy. The structural features of the mitochondrial spheroids thus represent a novel mitochondrial dynamics.     

Differential processing of cytosolic and mitochondrial caspases

The mitochondria have been shown to play a key role in the initiation of caspase activation during apoptosis. Recently, some caspases have been shown to be associated with mitochondria. In this study, we used Jurkat T-lymphoblasts to show that caspases -2 and -3 are located in the mitochondrial intermembrane space, associated with the inner membrane. Caspase-9 is associated with the outer membrane and is exposed to the cytosolic compartment. Caspase activation took place predominantly in the cytosol in response to Fas ligation, but staurosporine treatment led to caspase activation in both cytosol and mitochondria. In response to both Fas and staurosporine treatment, caspase processing could be detected earlier in cytosol than in mitochondria, but this could reflect the limits of sensitive detection by immunoblotting. Only trace amounts of Apaf-1 were found in association with the mitochondria. However, staurosporine treatment led to preferential auto-processing of caspase-9 associated with mitochondria. These findings suggest that mitochondrial caspases are regulated independently of the cytosolic pool of caspases. The data are also consistent with the notion of a caspase nucleation site associated with mitochondria. Using a stable transfected CEM cell line, we show that Bcl-2 suppressed caspase processing in both cytosolic and mitochondrial compartments in response to both staurosporine and Fas ligation.     

Human skeletal muscle: participation of different metabolic activities in oxidation of L-lactate.

The pure mitochondrial fraction obtained from human skeletal muscle did not show coupled L-lactate (+ NAD) oxidation, but this function could be restored by addition of LDH. Thus the "direct", coupled oxidation of L-lactate described earlier (Popinigis et al., 1990. International Perspectives in Exercise Physiology, Human Kinetics Books, pp. 132-133) should be attributed to contaminations.     

Targeting of a chemically pure preprotein to mitochondria does not require the addition of a cytosolic signal recognition factor.

To analyze the role of cytosolic cofactors in mitochondrial protein targeting, we prepared a chemically pure mitochondrial preprotein. When diluted out of 7 M urea, this precursor protein was efficiently imported into mitochondria without the addition of cytosolic cofactors. Extensive prewashing of mitochondria (up to 2 M KCl) did not reduce its import. Import of the purified precursor showed the characteristics of authentic mitochondrial import including use of the receptor MOM19, requirement for a membrane potential, and proteolytic processing. When the precursor was preincubated at a low concentration of urea, cytosolic cofactors were needed to preserve its import competence. We conclude that targeting of this preprotein via the mitochondrial master receptor MOM19 does not require a cytosolic signal recognition factor; cytosolic cofactors apparently have chaperone-like functions in mitochondrial protein uptake. Moreover, we found that a cleavable presequence was sufficient to direct protein import via MOM19. Together with the cofactor-independent function of MOM19, it is thus conceivable that MOM19 functions as mitochondrial presequence receptor.     

Intracellular distribution and biosynthesis of lipoamide dehydrogenase in rat liver

Lipoamide dehydrogenase (LADase) was purified to homogeneity from rat liver mitochondria, and the intracellular distribution and biosynthesis of the LADase were investigated with antibody prepared against the purified enzyme. 1) LADase activity was mostly found in mitochondria; the activity in cytosol was about one-tenth of that in mitochondria. 2) LADase in the crude mitochondrial and cytosolic extracts and the purified LADase were immunologically identical as judged from the Ouchterlony double diffusion test. These LADases were indistinguishable from each other on immunochemical titration; i.e., the amount of LADase precipitated by a fixed amount of the anti-LADase antibody was the same for all the preparations. However, cytosolic LADase activity was inhibited by the antibody more strongly than mitochondrial LADase activity. 3) Two min after intravenous injection of [35S]methionine, more radioactivity was incorporated into cytosolic LADase than into the mitochondrial enzyme in the liver. This result suggests that localization of LADase in the cytosolic fraction is not an artifact due to leakage from mitochondria during homogenization of rat liver. 4) LADase was synthesized predominantly on free ribosomes, which indicates that LADase is synthesized on cytoplasmic ribosomes and translocated into mitochondria just as other mitochondrial proteins are. 5) After cell-free protein synthesis with post-mitochondrial supernatant, radioactivity immunoprecipitated with anti-LADase antibody was detected as a major peak with the same molecular weight as the purified LADase.     

Physical and Functional Association of Lactate Dehydrogenase (LDH) with Skeletal Muscle Mitochondria

The intracellular lactate shuttle hypothesis posits that lactate generated in the cytosol is oxidized by mitochondrial lactate dehydrogenase (LDH) of the same cell. To examine whether skeletal muscle mitochondria oxidize lactate, mitochondrial respiratory oxygen flux (JO₂) was measured during the sequential addition of various substrates and cofactors onto permeabilized rat gastrocnemius muscle fibers, as well as isolated mitochondrial subpopulations. Addition of lactate did not alter JO₂. However, subsequent addition of NAD⁺ significantly increased JO₂, and was abolished by the inhibitor of mitochondrial pyruvate transport, α-cyano-4-hydroxycinnamate. In experiments with isolated subsarcolemmal and intermyofibrillar mitochondrial subpopulations, only subsarcolemmal exhibited NAD⁺-dependent lactate oxidation. To further investigate the details of the physical association of LDH with mitochondria in muscle, immunofluorescence/confocal microscopy and immunoblotting approaches were used. LDH clearly colocalized with mitochondria in intact, as well as permeabilized fibers. LDH is likely localized inside the outer mitochondrial membrane, but not in the mitochondrial matrix. Collectively, these results suggest that extra-matrix LDH is strategically positioned within skeletal muscle fibers to functionally interact with mitochondria.     

Mitochondrial modulation of calcium signaling at the initiation of development

Fertilization triggers cytosolic Ca(2+) oscillations that activate mammalian eggs and initiate development. Extensive evidence demonstrates that Ca(2+) is released from endoplasmic reticulum stores; however, less is known about how the increased Ca(2+) is restored to its resting level, forming the Ca(2+) oscillations. We investigated whether mitochondria also play a role in activation-associated Ca(2+) signaling. Mitochondrial dysfunction induced by the mitochondrial uncoupler FCCP or antimycin A disrupted cytosolic Ca(2+) oscillations, resulting in sustained increase in cytosolic Ca(2+), followed by apoptotic cell death. This suggests that functional mitochondria may participate in sequestering the released Ca(2+), contributing to cytosolic Ca(2+) oscillations and preventing cell death. By centrifugation, mouse eggs were stratified and separated into fractions containing both endoplasmic reticulum and mitochondria and fractions containing endoplasmic reticulum with no mitochondria. The former showed Ca(2+) oscillations by activation, whereas the latter exhibited sustained elevation in cytosolic Ca(2+) but no Ca(2+) oscillations, suggesting that mitochondria take up released cytosolic Ca(2+). Further, using Rhod-2 for detection of mitochondrial Ca(2+), we found that mitochondria exhibited Ca(2+) oscillations, the frequency of which was not different from that of cytosolic Ca(2+) oscillations, indicating that mitochondria are involved in Ca(2+) signaling during egg activation. Therefore, we propose that mitochondria play a crucial role in Ca(2+) signaling that mediates egg activation and development, and apoptotic cell death.     

Mitochondrial affinity for ADP is twofold lower in creatine kinase knock-out muscles. Possible role in rescuing cellular energy homeostasis

Adaptations of the kinetic properties of mitochondria in striated muscle lacking cytosolic (M) and/or mitochondrial (Mi) creatine kinase (CK) isoforms in comparison to wild-type (WT) were investigated in vitro. Intact mitochondria were isolated from heart and gastrocnemius muscle of WT and single- and double CK-knock-out mice strains (cytosolic (M-CK-/-), mitochondrial (Mi-CK-/-) and double knock-out (MiM-CK-/-), respectively). Maximal ADP-stimulated oxygen consumption flux (State3 Vmax; nmol O2 x mg mitochondrial protein(-1) x min(-1)) and ADP affinity (K50ADP; microM) were determined by respirometry. State 3 Vmax and of M-CK-/- and MiM-CK-/- gastrocnemius mitochondria were twofold higher than those of WT, but were unchanged for Mi-CK-/-. For mutant cardiac mitochondria, only the of mitochondria isolated from the MiM-CK-/- phenotype was different (i.e. twofold higher) than that of WT. The implications of these adaptations for striated muscle function were explored by constructing force-flow relations of skeletal muscle respiration. It was found that the identified shift in affinity towards higher ADP concentrations in MiM-CK-/- muscle genotypes may contribute to linear mitochondrial control of the reduced cytosolic ATP free energy potentials in these phenotypes.     

Differential import of nuclear-encoded tRNAGly isoacceptors into solanum Tuberosum mitochondria

In potato ( Solanum tuberosum ) mitochondria, about two-thirds of the tRNAs are encoded by the mitochondrial genome and one-third is imported from the cytosol. In the case of tRNAGly isoacceptors, a mitochondrial-encoded tRNAGly(GCC) was found in potato mitochondria, but this is likely to be insufficient to decode the four GGN glycine codons. In this work, we identified a cytosolic tRNAGly(UCC), which was found to be present in S.tuberosum mitochondria. The cytosolic tRNAGly(CCC) was also present in mitochondria, but to a lesser extent. By contrast, the cytosolic tRNAGly(GCC) could not be detected in mitochondria. This selective import of tRNAGly isoacceptors into S. tuberosum mitochondria raises further questions about the mechanism under-lying the specificity of the import process.     

Intracellular iron trafficking: role of cytosolic ligands

Iron acquired by cells is delivered to mitochondria for metabolic processing via pathways comprising undefined chemical forms. In order to assess cytosolic factors that affect those iron delivery pathways, we relied on microscopy and flow-cytometry for monitoring iron traffic in: (a) K562 erythroleukemia cells labeled with fluorescent metal-sensors targeted to either cytosol or mitochondria and responsive to changes in labile iron and (b) permeabilized cells that retained metabolically active mitochondria accessible to test substrates. Iron supplied to intact cells as transferrin-Fe(III) or Fe(II)-salts evoked concurrent metal ingress to cytosol and mitochondria. With either supplementation modality, iron ingress into cytosol was mostly absorbed by preloaded chelators, but ingress into mitochondria was fully inhibited only by some chelators, indicating different cytosol-to-mitochondria delivery mechanisms. Iron ingress into cytosol or mitochondria were essentially unaffected by depletion of cytosolic iron ligands like glutathione or the hypothesized 2,5 dihydroxybenzoate (2,5-DHBA) siderophore/chaperone. These ligands also failed to affect mitochondrial iron ingress in permeabilized K562 cells suspended in cytosol-simulating medium. In such medium, mitochondrial iron uptake was >6-eightfold higher for Fe(II) versus Fe(III), showed saturable properties and submicromolar K(1/2) corresponding to cytosolic labile iron levels. When measured in iron(II)-containing media, ligands like AMP, ADP or ATP, did not affect mitochondrial iron uptake whereas in iron(III)-containing media ADP and ATP reduced it and AMP stimulated it. Thus, cytosolic iron forms demonstrably contribute to mitochondrial iron delivery, are apparently not associated with DHBA analogs or glutathione but rather with resident components of the cytosolic labile iron pool.     

Regulating effect of mitochondrial lactate dehydrogenase on oxidation of cytoplasmic NADH via an "external" pathway in skeletal muscle mitochondria.

1. The specific activity of lactate dehydrogenase of skeletal muscle mitochondria was found to be 2.5 times lower than specific activity of total NADH-cytochrome c reductase. 2. The specific activity of mitochondrial LDH in skeletal muscle mitochondria was almost equal to the activity of rotenone-insensitive NADH-cytochrome c reductase. 3. Mitochondrial LDH acting as an oxidase of lactate to pyruvate may feed an "external" pathway, but the activity of the mitochondrial enzyme is a limiting factor in oxidation of lactate-derived NADH. 4. Mitochondrial LDH acting as a reductase of pyruvate to lactate successfully competes with an "external" pathway for cytoplasmic NADH. 5. Exogenous NADH oxidation via an "external" pathway was inhibited by pyruvic acid. This inhibition was overcome by addition of oxamic acid or hydrazine.     

Demonstration of glyoxalase II in rat liver mitochondria. Partial purification and occurrence in multiple forms

Glyoxalase II (S-(2-hydroxyacyl)glutathione hydrolase, EC 3.1.2.6), which has been regarded as a cytosolic enzyme, was also found in rat liver mitochondria. The mitochondrial fraction contained about 10-15% of the total glyoxalase II activity in liver. The actual existence of the specific mitochondrial glyoxalase II was verified by showing that all of the activity of the crude mitochondrial pellet was still present in purified mitochondria prepared in a Ficoll gradient. Subfractionation of the mitochondria by digitonin treatment showed that 56% of the activity resided in the mitochondrial matrix and 19% in the intermembrane space. Partial purification of the enzyme (420-fold) was also achieved. Statistically significant differences were found in the substrate specificities of the mitochondrial and the cytosolic glyoxalase II. Electrophoresis and isoelectric focusing of either the crude mitochondrial extract or of the purified mitochondrial glyoxalase II resolved the enzyme activity into five forms with the respective pI values of 8.1, 7.5, 7.0, 6.85 and 6.6. Three of these forms (pI values 7.0-6.6) were exclusively mitochondrial, with no counterpart in the cytosol. The relative molecular mass of the partially purified enzyme, as estimated by Superose 12 gel chromatography, was 21,000. These results give evidence for the presence of mitochondrial glyoxalase II which is different from the cytosolic enzymes in several characteristics.     

Cytosolic yeast tRNA(His) is covalently modified when imported into mitochondria of Trypanosoma brucei.

The mitochondrial genome of Trypanosoma brucei does not encode any tRNAs. Instead, mitochondrial tRNAs are synthesized in the nucleus and subsequently imported into mitochondria. The great majority of mitochondrial tRNAs have cytosolic counterparts showing identical primary sequences. The only difference found between mitochondrial and cytosolic isotypes of the tRNAs are mitochondria-specific nucleotide modifications which appear to be a common feature of imported tRNAs in trypanosomes. In this study, a mutated yeast cytosolic tRNAHis was expressed in trypanosomes and its import phenotype was analyzed by cell fractionation and nuclease treatment of intact mitochondria. Furthermore, cytosolic and mitochondrial isotypes of the yeast tRNA(His) were specifically labeled and analyzed by limited alkaline hydrolysis. These experiments revealed the presence of mitochondria-specific nucleotide modifications in the yeast tRNA(His). The positions of the modifications were determined by direct enzymatic sequencing of the tRNA(His) and shown to correspond to the ultimate and penultimate nucleotides before the anticodon, the same relative positions which are modified in the mitochondrial isotype of trypanosomal tRNA(Tyr). The results demonstrate that covalent modification of tRNAs; in trypanosomal mitochondria can be used, in analogy to processing of precursor proteins during mitochondrial protein import, as a marker for import of both endogenous and heterologous tRNAs.