Divergent Regulation of Protein Synthesis in the Cytosol and Endoplasmic Reticulum Compartments of Mammalian Cells

Samuel B. Stephens, and Christopher V. Nicchitta

Department of Cell Biology, Duke University Medical Center, Durham, NC 27710

Submitted July 18, 2007; Revised November 19, 2007; Accepted November 29, 2007
Monitoring Editor: Marvin P. Wickens

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In eukaryotic cells, mRNAs encoding signal sequence-bearingproteins undergo translation-dependent trafficking to the endoplasmicreticulum (ER), thereby restricting secretory and integral membraneprotein synthesis to the ER compartment. However, recent studiesdemonstrating that mRNAs encoding cytosolic/nucleoplasmic proteinsare represented on ER-bound polyribosomes suggest a global rolefor the ER in cellular protein synthesis. Here, we examinedthe steady-state protein synthesis rates and compartmental distributionof newly synthesized proteins in the cytosol and ER compartments.We report that ER protein synthesis rates exceed cytosolic proteinsynthesis rates by 2.5- to 4-fold; yet, completed proteins accumulateto similar levels in the two compartments. These data suggestthat a significant fraction of cytosolic proteins undergo synthesison ER-bound ribosomes. The compartmental differences in steady-stateprotein synthesis rates correlated with a divergent regulationof the tRNA aminoacylation/deacylation cycle. In the cytosol,two pathways were observed to compete for aminoacyl-tRNAs—proteinsynthesis and aminoacyl-tRNA hydrolysis—whereas on theER tRNA deacylation is tightly coupled to protein synthesis.These findings identify a role for the ER in global proteinsynthesis, and they suggest models where compartmentalizationof the tRNA acylation/deacylation cycle contributes to the regulationof global protein synthesis rates.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Early studies into the mechanism of protein secretion establishedthe endoplasmic reticulum (ER) as the site of secretory andintegral membrane protein synthesis (Palade and Siekevitz, 1956a,b;Siekevitz and Palade, 1958). The subsequent discovery of thesignal recognition particle pathway provided important insightinto the mRNA partitioning events that enable the compartmentalizationof secretory/integral membrane protein biogenesis to the ER(Blobel and Dobberstein, 1975a,b; Walter and Blobel, 1981a,b).This process is initiated when cytosolic mRNA/ribosome/nascentchain complexes (RNCs) engaged in the synthesis of secretoryor integral membrane proteins undergo high-affinity interactionswith the signal recognition particle (SRP). SRP binding elicitsa suppression of translation and enables the trafficking ofmRNA/ribosome/nascent chain complexes to the ER (Meyer and Dobberstein,1980; Walter and Blobel, 1981a,b; Walter et al., 1981; Gilmoreet al., 1982a,b). At the ER, sequential RNC binding interactionswith the SRP receptor and Sec61p yield SRP release, ribosomebinding to Sec61p, and an ER-restricted process of coupled proteinsynthesis/protein translocation (Blobel and Dobberstein, 1975b;Blobel et al., 1979; Walter and Lingappa, 1986; Gorlich et al.,1992). Consistent with this "positive selection" model, genome-widestudies of mRNA partitioning between cytosolic and membrane-boundribosomes, conducted in yeast, fly, rodent, and human modelsystems demonstrate the expected enrichment of mRNAs encodingsecretory/integral membrane proteins on the ER membrane (Mechlerand Rabbitts, 1981; Mueckler and Pitot, 1981; Kopczynski etal., 1998; Diehn et al., 2000; Lerner et al., 2003). These studiesalso demonstrated that mRNAs encoding cytosolic/nucleoplasmicproteins are broadly represented on ER-bound polyribosomes witha small cohort of mRNAs being highly ER enriched (Mechler andRabbitts, 1981; Mueckler and Pitot, 1981; Kopczynski et al.,1998; Diehn et al., 2000, 2006). Because these mRNAs do notencode signal sequences or transmembrane domains, these observationsindicate that additional mechanisms function in the partitioningof mRNAs in eukaryotic cells, and they suggest possible rolesfor the ER in global protein synthesis.

In addition to studies of mRNA partitioning, biochemical andmolecular genetic analyses of cellular protein synthesis alsosuggest a more global role for the ER in protein synthesis regulation.For example, studies conducted using an in vitro rough microsome-directedtranslation system have demonstrated that membrane-bound ribosomescan initiate de novo mRNA translation; moreover, they are capableof synthesizing cytosolic and secretory/integral membrane proteins(Potter and Nicchitta, 2000). Furthermore, molecular geneticanalyses of the SRP pathway in Saccharomyces cerevisiae suggestthat the loss of SRP/SRP receptor function can be compensatedfor by enhanced protein synthesis initiation on ER-bound ribosomes(Mutka and Walter, 2001). A physiological role for the ER inthe synthesis of cytosolic/nucleoplasmic proteins has been demonstratedto occur in response to induction of the unfolded protein response(UPR) or picornavirus infection, stress conditions that elicitthe suppression of protein synthesis via different mechanisms(Stephens et al., 2005; Lerner and Nicchitta, 2006). In thesestudies, cell stress-dependent inactivation of eukaryotic initiationfactor (eIF)2 ${alpha}$ activity or proteolytic inactivation of eIF4G,resulted in a marked inhibition of cytosolic protein synthesis.In contrast, protein synthesis on the ER was sustained, withcytosolic/nucleoplasmic- and secretory/integral membrane-encodingmRNAs undergoing ER-restricted translation (Stephens et al.,2005; Lerner and Nicchitta, 2006).

In this report, we examined the steady-state protein synthesisactivities of the cytosol and ER compartments. Using in situradioisotope pulse-chase labeling studies of ribosome-boundnascent chains, we report that the protein synthesis activityof ER-bound ribosomes is 2.5- to 4-fold higher than cytosolicribosomes. Consistent with this observation, using a globinreporter system, we observed a 3.5-fold increase in the levelof globin protein synthesized on the ER membrane relative tosynthesis directed by cytosolic ribosomes. Complementing thesefindings, the cytosol and ER compartments displayed distinctpathways of tRNA deacylation; in the cytosol, aminoacyl-tRNAdeacylation could occur independent of protein synthesis; incontrast, on the ER, the deacylation of aminoacyl-tRNAs wastightly coupled to protein synthesis. This study demonstratesthat the cytosol and ER compartments differ substantially intheir protein synthesis capacities, and they suggest that thecompartmental regulation of tRNA deacylation pathways may contributeto these differences.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Reagents
[³⁵S]Methionine/cysteine (1175 Ci/mmol) was obtained from MPBiomedicals (Irvine, CA). [(3,4,5)-³H]Leucine (100 Ci/mmol)was from MP Biomedicals and PerkinElmer Life and AnalyticalSciences (Boston, MA). Digitonin was from Calbiochem (San Diego,CA). Cycloheximide was from Sigma-Aldrich (St. Louis, MO). Hybondmembrane was from GE Healthcare (Chalfont St. Giles, UnitedKingdom). Cell culture reagents were from Invitrogen (Carlsbad,CA) with the exception of leucine-deficient media, which wasprovided by Millipore Specialty Media (Billerica, MA). RNaseOUT, pcDNA6.1B-myc, Lipofectamine 2000, and Alexa Fluor-conjugatedantibodies were from Invitrogen. β-Tubulin antibody (E7)was from the Iowa Developmental Studies Hybridoma Bank (Universityof Iowa, Iowa City, IA). Anti-myc epitope antibody was fromAbcam (Cambridge, MA).

Cell Culture
HeLa, human embryonic kidney (HEK)293, and Cos7 cells were culturedin DMEM supplemented with 10% fetal calf serum at 37°C with5% CO₂. For most experiments, cells were used at $~$ 80% confluence.In transfection experiments, conducted in Cos7 cells, cell densitywas at 85–95% confluence, plasmid concentrations were250 ng/well (six-well plate), and transfections were conductedaccording to the manufacturer's instructions. At 4–5 hafter transfection, cells were trypsinized and split into pairedwells of a six-well dish for overnight culture. Experimentswere performed at 24 h after transfection.

Sequential Detergent Extraction
The cytosol and ER compartments were obtained by a sequentialdetergent extraction protocol (Lerner et al., 2003; Stephenset al., 2005, 2007; Lerner and Nicchitta, 2006). Briefly, cellmonolayers were washed with phosphate-buffered saline, and theywere incubated with 0.3–0.5 ml (12-well) or 0.6–1.0ml (six-well) of permeabilization buffer [110 mM KOAc, 25 mMK-HEPES, pH 7.2, 2.5 mM Mg(OAc)₂, 1 mM EGTA, 1 mM dithiothreitol(DTT), 1 mM phenylmethylsulfonyl fluoride (PMSF), and 10 U/mlRNase Out] containing 0.015% digitonin for 5 min on ice. Thesupernatant (cytosol) was recovered, and cells were washed oncewith permeabilization buffer containing 0.004% digitonin. Permeabilizedcell monolayers were then solubilized with an equivalent volumeof NP-40/sodium deoxycholate (DOC) lysis buffer [400 mM KOAc,25 mM K-HEPES, pH 7.2, 15 mM Mg(OAc)₂, 1% NP-40, 0.5% DOC, 1mM DTT, 1 mM PMSF, and 10 U/ml RNase Out] for 5 min on ice.The supernatant (membrane-bound fraction) was recovered, andboth cytosol and membrane-bound fractions were clarified bycentrifugation at 7500 x g for 10 min at 4°C. Buffers weresupplemented with 0.2 mM cycloheximide where applicable. Forribosome isolation, equal volumes of cytosol and membrane-boundfractions were aliquoted, and cytosol fractions were adjustedto 1% NP-40 and 12. 5 mM Mg(OAc)₂. Lysates were layered overa 1.0 M sucrose cushion, and ribosomes were collected by centrifugationat 90,000 rpm in a TLA100.2 (Beckman Coulter, Fullerton, CA)rotor for 40 min at 4°C.

Metabolic Radiolabeling of Cell Cultures
Cell media were replaced with prewarmed methionine-deficientDMEM (supplemented with 1 mM sodium pyruvate, 1 mM glutamine,and 25 mM K-HEPES, pH 7.5) containing 0.2 mCi/ml [³⁵S]methionine/cysteine(Met/Cys) (or leucine deficient DMEM containing 0.3–0.5mCi/ml [³H]Leu) and cultured for the indicated times (withoutprior amino acid starvation). Where indicated, protein synthesiswas inhibited by addition of 0.2 mM cycloheximide, and chaseprotocols were initiated by rapid replacement of the cell mediawith normal growth media supplemented with 1 mM unlabeled methionine(or leucine). For tRNA-based experiments, the time points representthe absolute time of labeling (and cycloheximide treatment).For pulse-chase tRNA labeling experiments, the chase was initiatedby addition of 1 mM unlabeled methionine (or leucine) to thelabeling media. Cycloheximide (0.2 mM) was added as indicated.

Velocity Sedimentation Analysis
HeLa cells cultured in a 175 cm² flask at $~$ 80% confluence werestarved for 10 min in methionine-deficient media and pulse labeledfor 2 min with 1 mCi/ml [³⁵S]Met/Cys and subsequently treatedwith 0.2 mM cycloheximide. Clarified cytosol and membrane-boundfractions were resolved by centrifugation through 10 ml 15–50%linear sucrose gradients at 151,000 x g for 3 h in a SW41 Beckmanrotor. Fractions were manually collected, and the UV (260 nm)absorbance was determined. Then, 15-µl aliquots of fractionswere analyzed by liquid scintillation spectrometry. For SDS-PAGE/phosphorimageranalysis, total protein was isolated by TCA precipitation, resuspendedin SDS-polyacrylamide gel electrophoresis (PAGE) sample buffer(0.5 M Tris base, pH $~$ 11, 5% SDS, 4% glycerol, 0.02% bromphenolblue, and 100 mM 2-mercaptoethanol), heated at 65°C for15 min, and resolved by SDS-PAGE on 12.5% gels. Radioisotopeincorporation was determined by phosphorimager analyses of thedried gels.

Radiolabel Incorporation into Total Protein and Ribosome-bound Nascent Polypeptide Chains
Ribosome pellets were resuspended in 50 µl of 0.5 M Trisbase, pH $~$ 11, 5% SDS, and heated at 65°C for 10 min to hydrolyzeaminoacyl-tRNA ester linkages. Ribosome samples and 10- to 20-µlaliquots of total protein (removed before ultracentrifugation)were spotted onto 1-inch squares of 3MM filter paper and immersedin 10% ice-cold trichloroacetic acid (TCA) for 15 min. Filterswere then placed in boiling 5% TCA for 15 min, rinsed with 5%TCA, immersed in ethanol:ether (1:1) for 5 min, and transferredto ether for 5 min. Filters were dried and quantified by liquidscintillation spectrometry. For kinetic experiments, data weregraphed using one-phase exponential decay nonlinear regressioncurve fitting (GraphPad Software, San Diego, CA).

For the in vitro aminoacylation reaction, 0.1 ml of Met-tRNAreaction buffer [100 mM KOAc, 50 mM K-HEPES, pH 7.2, 10 mM Mg(OAc)₂,5 mM ATP, 5 mM DTT, 0.1 mg/ml calf liver tRNA, 10 µM methionine,and 1 µCi of 1 µM [³⁵S]methionine/cysteine] wasadded to 10 µl of cell lysate (0.5–1.0 x 10⁴ cellequivalents) and incubated at 37°C for 10 min. Reactionswere stopped by the addition of 0.4 ml of cold 10% TCA and icedfor 10 min. Samples were collected and washed by vacuum filtrationand quantified by liquid scintillation spectrometry.

Plasmid Construction
The vector pTetBBB containing a genomic sequence of rabbit β-globinwas a kind gift from Dr. A.-B. Shyu (University of Texas HoustonMedical School, Houston, TX). The myc epitope was inserted atthe BamHI site by using phosphorylated primers (sense, 5'-GATCCTGAACAAAAACTCATCTCAGGAGAGGATCTCGG-3';antisense, 5'-GATCCGAGATCCTCTTCTGAGATGAGTTTTTGTTCAG-3'). Thefull-length globin sequence was subcloned into a HindIII/XhoIsite in pcDNA6.1B after generation of restriction site bearingcoding region via polymerase chain reaction (PCR), by usingthe primers (sense, 5'-GTGACTAAGCTTACCATGGTGCATCTGTCCAG-3';antisense, 5'-GAGACACTCGAGTGCAATGAAAATAAATTTCC-3'). The immunoglobulin ${kappa}$ signal sequence was inserted into the HindIII site at the aminoterminus of the globin-coding region by using overlapping phosphorylatedprimers (sense, 5'-AGCTTACCATGGAGACAGACACACTCCTGCTATGGGTACTGC-3'and 5'-TGCTCTGGGTTCCAGGTTCCACTGGTGACA-3'; antisense, 5'-AGCAGGAGTGTGTCTGTCTCCATGGTA-3'and 5'-AGCTTGTCACCAGTGGAACCTGGAACCCAGAGCAGCAGTACCCAT-3'). Allsequences were verified (Duke University Comprehensive CancerDNA Sequencing Facility, Durham, NC).

RNA Analysis
RNA was isolated from cell lysates or ribosome fractions byusing a phenol-chloroform based extraction protocol (Stephenset al., 2007). RNA was resolved on 1% agarose/3% formaldehydedenaturing gels and stained with ethidium bromide. Ethidiumbromide fluorescence was determined using a Typhoon Trio 9400(GE Healthcare). Agarose gels were transferred to Hybond membranesin 5x SSC + 10 mM NaOH by downward capillary flow for 2 h andUV cross-linked at 1200 mJ. For tRNA-radiolabeling studies,membranes were directly exposed to phosphorimager plates ([³⁵S]Met)or quantified by liquid scintillation ([³H]Leu). For Northernblots, membranes were probed with an ³²P-end-labeled antisenseoligonucleotide (directed against the myc epitope encoding domain).

Immunoprecipitations
Total cell lysates were generated by solubilization of cellmonolayers in 25 mM Tris, pH 7.5, 150 mM NaCl, 5 mM EDTA, 1%NP-40, 0.05% SDS, 1 mM DTT, and 0.5 mM PMSF. Lysates were clarifiedby centrifugation at 7500 x g for 10 min at 4°C. Globinproteins was immunoprecipitated using a 1:200 antibody dilutionand 20 µl of protein A-Sepharose slurry (50%) rotatingend over end for 1 h at room temperature. Beads were washedin lysis buffer and heated at 95°C for 10 min in SDS-PAGEsample buffer. Proteins were resolved by 12.5% SDS-PAGE or 18%SDS-PAGE (globin), and dried gels were exposed to phosphorimagerplates.

Phosphorimager plates were scanned using a Typhoon 9400 (GEHealthcare) and quantified using ImageQuantTL version 2003 software(GE Healthcare). Images were assembled in Adobe Photoshop 7.0(Adobe Systems, Mountain View, CA). Graphs were generated usingGraphPad Prism 4.0 software (GraphPad Software).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

It has recently been reported that cytosolic and ER membrane-directedprotein synthesis can undergo differential regulation in mammaliancells (Stephens et al., 2005; Lerner and Nicchitta, 2006). Forexample, cell stress arising from either activation of the UPRor picornaviral infection results in suppression of cytosolicmRNA translation, whereas translation on ER membrane-bound ribosomesis sustained (Stephens et al., 2005; Lerner and Nicchitta, 2006).In these scenarios, the ER functions as the predominant siteof global protein synthesis, and it engages in the synthesisof cytosolic and nucleoplasmic proteins, such as ATF4 and XBP-1(s),and secretory and integral membrane proteins. Extending fromthese studies, we postulated that under normal homeostatic growthconditions, the protein synthesis capacities of the two cellularcompartments may differ. To explore this possibility, we useda radioisotope pulse-labeling/cell fractionation assay to assessthe steady-state in situ protein synthesis activities of thecytosol and ER compartments. In this assay, cells are pulselabeled for 10 min with [³⁵S]methionine/cysteine, and radiolabelingis blocked by addition of excess unlabeled methionine. To documentisotope incorporation at time points during the labeling andchase periods, cell aliquots were treated with the elongationinhibitor cycloheximide (0.2 mM) at varying times. In Figure 1,cell samples (n = 3) were treated with cycloheximide at threetimes: 1) at the beginning of the pulse (t = 0 min), to assesscycloheximide-insensitive background isotope recovery; 2) atthe end of the 10-min pulse (t = pulse), to assess the maximallevel of isotope incorporation; and 3) at the end of the 15-minchase (t = chase), to assess the completion/release of newlysynthesized proteins. After the pulse-chase procedure, cellswere harvested and processed to yield distinct cytosolic andmembrane-bound subcellular fractions by using a sequential detergentextraction method (Seiser and Nicchitta, 2000; Potter and Nicchitta,2002; Lerner et al., 2003; Stephens et al., 2005, 2007). Tovalidate that the described fractionation methods were appropriateto these investigations, pulse-labeled cells were fractionatedat increasing time periods after isotope addition, and the subcellularfractions were analyzed for the accumulation of a newly synthesizedcytosolic (tubulin) and ER-resident (GRP94) protein. These dataare depicted in Supplemental Figure S1, and they demonstratethat the two fractions are highly enriched in their respectivenewly synthesized resident proteins, with little to no cross-contamination.To directly assay protein synthesis activity, ribosome-boundnascent chains (RNCs) were collected from the two subcellularfractions by ultracentrifugation of the subcellular fractions,and the isotopic protein content was analyzed by liquid scintillationspectrometry (Figure 1, A, C, and E). The labeling profilesof RNCs were compared with that of newly synthesized (i.e.,completed) proteins accumulating in the respective compartment(Figure 1, B, D, and F).

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Figure 1. Protein synthesis activity is enhanced in the ER compartment. HeLa (A and B), HEK293 (C and D), and Cos7 (E and F) cells were pulse labeled in methionine-deficient media with [³⁵S]Met/Cys for 10 min, and then they were chased for 15 min in normal growth media supplemented with 1 mM methionine. No prior amino acid starvation was performed. Cycloheximide (0.2 mM) was added to individual cell aliquots at the beginning of the pulse (0), the end of the pulse (pulse), or at the end of the chase (chase). Cytosol (cyt) and MB fractions were generated by sequential detergent extraction. Aliquots were removed for total protein (B, D, and F) and RNC fractions subsequently isolated by ultracentrifugation (A, C, and E). (A–F) Isotope incorporation was determined by liquid scintillation of the TCA-insoluble, alkaline-insensitive material. Mean values of replicate (n = 3) labeling experiments ± SE are displayed.

Using the methodology described above, the rates of proteinsynthesis and the compartmental fates of newly synthesized proteinswere determined for the cytosol and ER fractions of HeLa, HEK293,and Cos7 cells (Figure 1). As shown in Figure 1, ³⁵S-amino acidincorporation into RNCs was substantially higher in the membrane-boundribosome fractions of HeLa (Figure 1A), HEK293 (Figure 1C),and Cos7 (Figure 1E) cells. After the chase period, the quantitiesof ³⁵S-labeled RNCs returned to basal levels, demonstratingthe efficient release of the nascent polypeptide chain fraction.Quantification of these data indicated that the magnitude ofamino acid incorporation in the membrane-bound RNC fractionswas 2.5- to 4-fold higher than cytosolic RNC fractions (t =pulse), suggesting that steady-state protein synthesis rateson the ER are substantially higher than cytosolic rates. Todetermine whether differences in the ribosome content of thetwo compartments were responsible for this phenomenon, we determinedthe relative ribosome distribution between the cytosol and ERby quantifying 18S and 28S rRNA levels. Here, we observed that $~$ 45% of cellular ribosomes were recovered in the cytosol fractionin HeLa (Figure 2, A and C) and Cos7 (Figure 2, B and D) cells.Thus, the observed differences in the amino acid incorporationinto the RNC fractions could not be explained by differencesin ribosome distribution. Furthermore, given the very minoramount of mitochondrial ribosomes present in the membrane-bound(MB) fraction (compare relative intensities of ethidium bromidefluorescence of 28S/18S rRNA with 23S/16S mitochondrial rRNAin Figure 2, A and B, top, MB), it is unlikely that mitochondrialprotein synthesis contributed significantly to these findings.To account for potential differences in ribosome recovery, wealso assessed relative protein synthesis activities by usingribosome equivalents (Martin et al., 1969

). Although this lattermethod of analysis does not account for the presence of inactiveribosomes/ribosomal subunits, it does provide for a more directcomparison of protein synthesis activity. When normalized toa fixed quantity (500 fmol) of ribosomes, ER protein synthesisactivity was again 2.5- to 4-fold greater than cytosol activityin HeLa, HEK293, and Cos7 cells (Supplemental Figure S2A).

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Figure 2. Subcellular distribution of ribosomes, total tRNA, and newly charged tRNA. HeLa (A and C) and Cos7 (B and D) cells were pulse labeled with [³⁵S]Met/Cys for 5 min in methionine-deficient media. RNA from cyt and MB fractions was resolved on denaturing agarose (1%) gels and transferred to Hybond membrane. Relative rRNA and tRNA levels were determined by quantitative fluorescent imaging of the ethidium bromide-stained gels. Isotope incorporation was determined by phosphorimager analysis. Mean values of replicate labeling experiments (n = 3) ± SE are displayed.

In contrast to the isotope incorporation rates of RNCs, thelevels of accumulating (completed) newly synthesized proteinswere comparable between the cytosol and ER compartments (Figure 1,B, D, and F). These data suggest that a fraction of the proteinssynthesized on the ER were released to the cytosol. This interpretationis consistent with previous reports demonstrating that a broadarray of mRNAs encoding cytosolic and nucleoplasmic proteinscan be partitioned to and translated on membrane-bound ribosomes(Diehn et al., 2000

, 2006

; Lerner et al., 2003

; Stephens etal., 2005

). In addition, several reports have also demonstratedthat specific secretory proteins such as calreticulin and theplasminogen-activated inhibitor-2 protein (PAI-2) can be inefficientlytranslocated, and as a result, accumulate in the cytosol compartment(Belin et al., 1989

; Levine et al., 2005

). As an alternativepossibility, nascent polypeptides in the cytosol could be preferentiallydegraded as a consequence of the fractionation procedure. Totest the latter hypothesis, unlabeled and isotopically labeledcytosolic and ER fractions were reciprocally mixed (i.e., labeledcytosol + unlabeled MB and vice versa), and the radioactivityof RNCs and total protein fractions was subsequently assayedas described above. As shown in Figure 3, reciprocal mixingof subcellular fractions did not yield significant changes inrecovered radiolabeled RNCs or proteins. Furthermore, to assesswhether our observations were influenced by rapid protein (ornascent chain) turnover in situ, we determined the relativelevels of recovered radioactivity in the RNC fractions obtaineddirectly after the 10-min pulse or in cells treated with cycloheximideafter the 10-min pulse and harvested after the 15-min chase.Under both conditions, we consistently observed 2.5- to 4-foldhigher isotope incorporation into the membrane-bound RNC fraction(data not shown). Similarly, we compared the relative levelsof total newly synthesized protein, and again we did not observeany significant differences in the level of recovered radioactivity.These data indicate that the degradation of nascent chains and/orproteins either in situ or during the processing procedure didnot bias our observations.

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Figure 3. Newly synthesized proteins display identical stabilities in endoplasmic reticulum and cytosol fractions. HeLa cells were pulse labeled with [³⁵S]Met/Cys for 10 min in methionine-deficient media. Isotopically labeled cyt and MB fractions were mixed with cell equivalent quantities (volume) of either the reciprocal cellular fraction isolated from unlabeled cells or buffer alone and incubated for 20 min on ice. Aliquots were removed for total isotopic protein determinations, and the RNC fraction was isolated by ultracentrifugation. Isotope incorporation was determined by liquid scintillation of the TCA-insoluble, alkaline-insensitive material. Mean values of replicate (n = 3) labeling experiments ± SE are displayed. Recovered radioactivity was normalized to buffer alone.

To further characterize the differences in relative proteinsynthesis activities of the cytosol and ER membrane, detailedtime course studies of (isotopic) amino acid incorporation intocompleted protein and RNCs were performed. Cycloheximide treatmentwas used to halt protein synthesis at varying times of the pulse-chaseprocedure. In the experiments presented in Figure 4, A and Dand C and F, HeLa cells were pulse labeled with [³⁵S]Met/Cysor [³H]Leu, respectively, for 12 min. The time points reflectaddition of cycloheximide (0.2 mM) to individual cell aliquots(n = 3) at the indicated times of the pulse labeling. In Figure 4,A ([³⁵S]Met/Cys) and C ([³H]Leu), comparisons of in situ pulse-labelingkinetics of subcellular RNC fractions identified significantlyhigher rates and magnitudes of protein synthesis activity onthe ER membrane, consistent with data presented in Figure 1.In addition, the appearance of newly synthesized proteins wascomparable in rate and magnitude between the two compartments(Figure 4, D and F); no statistical difference in the levelof isotope incorporation into proteins was observed betweenthe two compartments by using either amino acid tracer. Notably,the differences in RNC incorporation were independent of labelingconditions used (i.e., amino acid-deficient vs. enriched culturemedia; Figure 4, A and D, and Supplemental Figure S2, B andC) or radiolabeled amino acid (methionine vs. leucine; Figure 4,A and D vs. C and F). Potentially, our observations could resultfrom delayed released kinetics of nascent chains from membrane-boundribosomes. To evaluate this possibility, we examined the turnoverkinetics (i.e., release) of nascent chains by using a pulse-chaseprocedure (Figure 4, B and E). In these experiments, cells werepulse labeled for 10 min and chased with excess unlabeled aminoacid for 12 min. Here, cycloheximide (0.2 mM) was added to cellaliquots (n = 3) at varying times of the chase, analogous tothe procedure described above used for pulse labeling. As shownin Figure 4B, both compartments exhibited rapid decay (release)kinetics of ribosome-bound nascent chains, demonstrating thatdelayed termination (i.e., nascent chain release) did not makea substantial contribution to the greater magnitude of membrane-boundRNC labeling.

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Figure 4. Protein synthesis is kinetically favored on the endoplasmic reticulum. HeLa cells were pulse labeled with [³⁵S]Met/Cys (A and D) for 12 min or [³H]Leu (C and F) for 15 min. (B and E) HeLa cells were pulse labeled with [³⁵S]Met/Cys for 10 min and chased in normal growth media supplemented with 1 mM methionine for 12 min. (A–F) Cycloheximide was added at the indicated times (closed squares and triangles) during the pulse (A, C, D, and F) or chase procedures (B and E). Aliquots were removed for total protein (D–F), and RNC fractions were subsequently isolated by ultracentrifugation (A–C). (A–F) Isotope incorporation was determined by liquid scintillation of the TCA-insoluble, alkaline-insensitive material. Mean values of replicate (n = 3) labeling experiments ± SE are displayed. The cyt is depicted as the solid line; MB fractions are the dotted lines. Background labeling, which was assessed by cycloheximide addition at time 0 of the pulse, was subtracted from all time points.

To provide additional experimental evidence that the analysesdescribed above indeed corresponded to polyribosomes, the cytosoland membrane-bound fractions of pulse-radiolabeled HeLa cellswere resolved by sucrose gradient velocity sedimentation, andthe radiolabeled polypeptide composition of gradient fractionswas analyzed. As shown in Figure 5, the gradient sedimentationprocedure resolved the ribosomal subunits (18S and 28S rRNA),the 80S monosome (downward arrow) and large polyribosome-containingfractions. As assessed by UV absorbance values (260 nm), approximatelyequal quantities of polyribosomes were recovered from both subcellularfractions. To assess amino acid incorporation into ribosome-boundnascent chains, gradient fractions were acid precipitated, resolvedby SDS-PAGE, and the incorporated radioactivity was determinedby phosphorimager analyses (Figure 5, C and D). Consistent withthe data depicted in Figures 1 and 2 and Supplemental FigureS2, when polyribosome-bound radiolabeled nascent polypeptidelevels were evaluated, the membrane-derived fraction displayedconsiderably higher radioisotope incorporation, and the enhancedincorporation was present throughout the polyribosome profile.Summation of the total radioactivity present in the peak polyribosome-containingfractions indicated that the membrane-bound nascent chains hadapproximately fivefold greater isotope levels than the cytosolfraction. As an additional component of this experiment, wealso evaluated the levels of isotopically charged (aminoacylated)-tRNAbetween the two compartments. For this analysis, total RNA wasisolated from individual gradient fractions, resolved by denaturingagarose gel, transferred, and radioactivity corresponding tothe tRNA determined by phosphorimager analysis. Here, we observedapproximately equivalent levels of [³⁵S]Met/Cys-tRNA in thepolyribosome fractions from the two subcellular (cytosol andER) compartments.

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Figure 5. Membrane-bound ribosomes display elevated rates of protein synthesis: velocity sedimentation of polyribosome-associated nascent polypeptides. HeLa cells were pulse labeled with [³⁵S]Met/Cys for 2 min. Cytosol (A and C) and membrane-bound (B and D) fractions were prepared and sedimented through 15–50% linear sucrose gradients for 3 h at 151,000 x g. Ribosomes were monitored by UV absorbance (solid black line), and the downward facing arrow denotes the 80S monosome peak. (A and B) RNA extracted from individual gradient fractions was resolved on denaturing agarose gels and transferred to Hybond membrane. Total rRNA (28S and 18S) and tRNA levels were determined by ethidium bromide fluorescence. Isotope incorporation was analyzed by phosphorimager analysis. The dotted line represents the percent radioactivity of the total [³⁵S]Met/Cys-tRNA signal per gradient. (C and D) Total radioactivity (dotted line) of individual gradient fractions was determined by liquid scintillation. Proteins were resolved by SDS-PAGE, and radioisotope incorporation was determined by phosphorimager analysis.

To determine whether the differences in the steady-state ratesof protein synthesis in the cytosol and ER compartments reflectedglobal synthesis rates, rather than variations in the translationrates of discrete subsets of mRNAs, we evaluated the synthesisrate of a reporter protein whose mRNA was targeted to eitherthe ER or the cytosol. For these experiments, myc-tagged globinprotein, expressed from the genomic rabbit β-globin sequence,was used as a common reporter. To direct globin (Gbn) mRNA tothe ER, an encoded N-terminal signal sequence derived from theimmunoglobulin (Ig) ${kappa}$ chain was appended 5' to the globin openreading frame (=ssGbn). To validate the activity of the signalpeptide in directing the partitioning of the globin mRNA tothe ER, Northern blot analyses of the cytosol and membrane fractionsof reporter-transfected cells were performed. As shown in Figure 6,A and B, globin mRNA (Gbn) strongly copurified ( $≥$ 80%) with thecytosol fraction, whereas addition of a signal sequence localizedglobin mRNA to the ER.

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Figure 6. Targeting globin mRNA to the ER membrane yields enhanced globin protein expression. Cos7 cells were either mock transfected (M) or transfected with plasmid encoding myc-tagged wild-type globin (Gbn) or myc-tagged globin containing an N-terminal signal sequence (ssGbn). (A and B) Northern blot analysis of RNA isolated from cytosol and membrane-bound fractions. (C and D) Cells were transfected in triplicate and analyzed for RNA and protein content. (C) RNA was isolated from total cell lysates and analyzed by Northern blot (Gbn) with ethidium bromide fluorescence of the rRNA as a loading control. (D) Cells were metabolically labeled with [³⁵S]Met/Cys and myc-tagged globin and GRP94 (loading control) isolated by indirect immunoprecipitation from total cell lysates. Samples were resolved by SDS-PAGE, and dried gels were analyzed by phosphorimager analysis. (E) Quantification of immunoprecipitations was performed using ImageQuantTL version 5.2 software. It should be noted that of the two ER forms of globin, the higher molecular weight species (ssGbn-myc), which consists of approximately half of the globin product, contains an additional methionine residue, totaling three methionine and one cysteine residue (Gbn-myc has 2 met and 1 cys); thus, there could be a maximal increase in specific activity of 33% of this band, or 15% of total recovered globin from pssGbn-transfected cells.

Using the two globin reporter constructs, the translation ratesof the two cellular compartments were compared. Cos7 cells transfectedwith equivalent levels of plasmid DNA encoding either wild-type(Gbn) or signal sequence globin (ssGbn) displayed similar mRNAexpression levels (Figure 6C; three independent transfectionexperiments are depicted). To assay protein synthesis levels,transfected cells (n = 3) were pulse labeled, and newly synthesizedglobin and GRP94 (loading control) proteins were isolated byimmunoprecipitation. As shown in Figure 6D with quantificationin Figure 6E, phosphorimager analysis of newly synthesized globinprotein demonstrated that 3.5-fold more globin protein was producedwhen globin mRNA was translated on ER-bound ribosomes (ssGbn)compared with globin protein produced on cytosolic ribosomes(Gbn). These data recapitulate the observations obtained inbiochemically fractionated cells (Figures 1

–3 and SupplementalFigure S2), and they are consistent with a model of enhancedprotein synthesis on the ER membrane.

As noted above, the observation that the protein synthesis rateson the ER compartment were substantially higher than the cytosol,yet approximately similar quantities of completed proteins wererecovered from the two fractions, suggests a net flux of proteinfrom the site of synthesis on the ER to the site of residence,the cytosol. To directly test for the existence of such a pathway,the signal sequence of an abundant, resident ER chaperone protein,GRP94, was deleted and the mRNA/protein expression patternsof myc epitope-tagged versions of control (wild type; WT), andsignal sequence-deleted ( ${Delta}$ SS) GRP94 was determined (SupplementalFigure S3, B–F). A schematic illustration of these constructsis shown in Supplemental Figure S3A. As depicted in SupplementalFigure S3, B and C, the mRNAs encoding the WT and ${Delta}$ SS GRP94 andthe protein products were expressed at near identical levels.Immunoblot analysis of the compartmental distribution of thetwo proteins demonstrated efficient partitioning of the WT formto the ER and the ${Delta}$ SS form to the cytosol (Supplemental FigureS3D). As additional controls for the subcellular fractionation,paired immunoblots for the cytosolic protein 90-kDa heat-shockprotein and the ER-resident protein TRAP ${alpha}$ confirmed that thetwo fractions were highly enriched in their respective proteins.Unexpectedly, deletion of the signal sequence did not substantiallyalter GRP94 mRNA localization to ER, with nearly 100% of theWT mRNA and 90% of the ${Delta}$ SS mRNA copurifying with the ER fractionof HeLa (Supplemental Figure S3E) and Cos7 cells (SupplementalFigure S3F). For comparison, the mRNAs encoding the residentER lumenal proteins BiP and calreticulin and the cytosolic/nucleoplasmicprotein histone H3.3 displayed the expected enrichment in theER and cytosol fractions, respectively (Supplemental FigureS3, E and F). The observation that deletion of the signal sequenceof a resident ER lumenal protein does not substantially alterits mRNA partitioning pattern is further developed in a recentcommunication from this laboratory (Pyhtila et al., 2008). Thedata presented in Supplemental Figure S3 demonstrate that inthe absence of a signal sequence, ER-directed translation of ${Delta}$ SS GRP94-encoding mRNAs results in complete recovery of GRP94protein in the cytosol, thus directly demonstrating an ER-to-cytosolpathway of protein synthesis and residence. It should also bementioned that previous investigations have observed a relatedphenomenon for the signal sequence-bearing proteins calreticulinand PAI-2, where both ER lumenal and cytosolic forms of theproteins are observed as the result of inefficient translocation(Belin et al., 1989; Levine et al., 2005).

The precise mechanism(s) contributing to the observed kineticadvantage for protein synthesis on the ER is under investigation.From simple topological considerations, cytosolic and ER-boundribosomes would be expected to use common pools of protein synthesisinitiation, elongation, and termination factors, aminoacyl-tRNAs,and nucleotides, and so it is not clear how divergent regulationof protein synthesis in the cytosol and ER could be established.Potentially, localizing the complex reactions of protein synthesisto the two-dimensional plane of the ER membrane would alonebe expected to provide a substantial kinetic advantage (Berry,2002). Of related interest, it has been reported that in detergent-permeabilizedtissue culture cells lacking cytosol, aminoacyl-tRNAs can beused by the protein synthesis machinery and subsequently rechargedwithout undergoing free exchange with a soluble pool (Negrutskiiand Deutscher, 1991, 1992; Stapulionis and Deutscher, 1995).This phenomenon, termed tRNA channeling, would be expected tosignificantly enhance protein synthesis rates (Negrutskii andDeutscher, 1991; Stapulionis and Deutscher, 1995). Extendingfrom these findings, we sought to determine whether the cycleof tRNA aminoacylation and deacylation in the cytosol and onthe ER are under common or distinct regulation in intact cells.To examine this, we first determined the relative distributionof total and newly charged (aminoacylated) tRNA from cytosoland membrane-bound fractions of HeLa and Cos7 cells. Total tRNAlevels were quantified from ethidium bromide fluorescence; newlycharged [³⁵S]Met/Cys-tRNA levels were determined by phosphorimageranalysis. As depicted in Figure 2, the distribution of newlycharged [³⁵S]Met/Cys-tRNA between the cytosol and ER compartmentsof HeLa and Cos7 cells was approximately equal, and it mirroredthe ribosome (rRNA) distribution (Figure 2). Total tRNA, incontrast, was highly enriched in the cytosol fraction, comprising70–90% of the cellular pool (Figure 2). Expressed relativeto the total tRNA, these data identify a substantial enrichmentof newly charged tRNA on the ER. Assays of the subcellular partitioningof methionyl-/cysteinyl-tRNA synthetase activities indicatedthat the enrichment of newly charged tRNAs on the ER could notbe attributed to the subcellular distribution of tRNA synthetaseactivity, which favored the cytosol (Supplemental Figure S4).

The subcellular regulation of the tRNA acylation/deacylationcycle was further examined in studies of the discharge kinetics(deacylation) of aminoacylated-tRNA in the context of the proteinsynthesis reaction. In these experiments, cells were eitherpulse labeled for 10 min or pulse labeled for 5 min and chasedfor 10 min, and the radioactivity present in tRNA was determinedby phosphorimager analysis as stated above for Figure 5. Inthis system, the deacylation reaction can be monitored as eitherthe discharge and subsequent recharging (aminoacylation) oftRNA (pulse labeling) or directly as the immediate dischargeof isotopically labeled tRNA, via a pulse-chase experiment.To determine the contribution of protein synthesis to aminoacyl-tRNAturnover, paired experiments were performed in the presenceof cycloheximide (0.2 mM). Importantly, cycloheximide was addedto individual cell aliquots in concert with addition of isotope(i.e., beginning of the pulse) for pulse labeling (Figure 7,C and D) or addition of excess unlabeled amino acid (i.e., beginningof chase) for pulse-chase experiments (Figure 7, A, B, E, andF). Thus, in this assay, the time points reflect the total timeof labeling (Figure 7, C and D) or chase (Figure 7, A, B, C,and F).

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Figure 7. tRNA aminoacylation/deacylation is subject to divergent regulation in the cytosol and ER compartments. Untreated (UT) and cycloheximide (CHX)-treated Cos7 (A and B) and HeLa (E and F) cultures were pulse labeled for 5 min with [³⁵S]Met/Cys or [³H]Leu, respectively, and chased with the appropriate unlabeled amino acid (1 mM) for periods up to 10 min. (C and D) UT and CHX-treated HeLa cultures were pulse labeled with [³⁵S]Met/Cys for periods up to 10 min. (A–F) Cycloheximide was administered in concert with either addition of isotope during the pulse (C and D) or addition of unlabeled amino acid during the chase (A, B, E, and F). The time points reflect the total time of pulse (C and D) or chase (A, B, E, and F) (open and closed triangles and squares). Total RNA from cyt and MB cell lysates was resolved on denaturing agarose gels and transferred to Hybond membrane. Total tRNA was analyzed by ethidium bromide fluorescence. Isotope incorporation was analyzed by phosphorimager analysis (A–D) or liquid scintillation spectrometry (E and F). (A–F) Control (untreated) data points are represented by the solid line, and cycloheximide-treated data points by the dotted line.

In the absence of cycloheximide (untreated [UT]), the kineticsof tRNA deacylation (chase) was similar in the cytosol and membrane-boundcompartments. Using either [³⁵S]Met/Cys (Figure 7, A and B)or [³H]Leu (Figure 7, E and F), charged tRNA was almost completelydeacylated in 2 min (chase). Correspondingly, tRNA was (re)-aminoacylated(pulse) in $~$ 2 and 4 min in HeLa and Cos7 cells, respectively(Figure 7, C and D; data not shown). Pulse and pulse-chase experimentsperformed in concert with the inhibition of translation elongation(cycloheximide; identical results obtained with emetine) revealedmarked differences in aminoacyl-tRNA turnover in the cytosoland ER compartments. In the cytosol, the inhibition of proteinsynthesis only modestly affected tRNA discharge rates (chase)(Figure 7, A and E); similarly the cytosolic aminoacylationreaction (pulse) was only slightly delayed by cycloheximide,suggesting that tRNA discharge can occur independent of theprotein synthesis reaction (Figure 7C). In contrast, aminoacyl-tRNAdeacylation on the ER membrane was tightly coupled to proteinsynthesis; in the presence of cycloheximide, the rate of aminoacyl-tRNAdischarge and subsequent (re)-acylation were dramatically suppressed,as demonstrated for both [³⁵S]Met/Cys- and [³H]leucyl-tRNA (Figure 7,B, D, and F). These results indicate that in the cytosol, aminoacyl-tRNAsare accessible to an as yet unidentified tRNA hydrolase activityand thus may participate in futile aminoacylation/deacylationcycles. On the ER membrane, in contrast, tRNA discharge is efficientlycoupled to protein synthesis. These data identify a complexsubcellular organization of the metabolic processes associatedwith tRNA aminoacylation and deacylation. The findings thataminoacyl tRNA use is tightly coupled to protein synthesis onthe ER, relative to the cytosol, suggests that compartmentalregulation of the tRNA aminoacylation cycle contributes to enhancedrates of protein synthesis on the ER.

DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study, we report three primary findings: 1) steady-stateprotein synthesis rates on the endoplasmic reticulum are 2.5-to 4-fold higher than in the cytosol. This was evident at botha global level, by evaluating amino acid incorporation kineticsinto ribosome/nascent chain complexes, and at a message-specificlevel, by using globin reporter mRNAs displaying opposing subcellularlocalizations; 2) a substantial fraction of proteins undergosynthesis on ER-bound ribosomes, yet reside in the cytosol compartment.Although this conclusion was deduced by comparing the relativelevels of amino acid incorporation into nascent polypeptidesversus completed newly synthesized proteins in the cytosol andER, and so is inferred, a direct demonstration of this pathwayby using a signal sequence deletion mutant of the ER chaperoneGRP94 confirmed that such a pathway can operate in mammaliancells (Pyhtila et al., 2008); 3) the tRNA aminoacylation/deacylationcycle is subject to divergent regulation between the cytosoland ER compartments of higher eukaryotic cells. In the cytosol,aminoacyl-tRNAs are discharged via two pathways: protein synthesisand an as yet poorly understood aminoacyl-tRNA hydrolase function.Conversely, tRNA deacylation on the ER is tightly coupled toprotein synthesis. Together, these studies implicate the ERmembrane as the primary site of cellular protein synthesis,and in this context it may be a critical site for regulatingposttranscriptional gene expression.

Whereas it is generally accepted that the ER compartment functionsuniquely in the biogenesis of secretory and integral membraneproteins, the data presented here suggest that the ER membranealso contributes a substantial portion of newly synthesizedproteins to the cytosol. This proposal is consistent with theestablished patterns of mRNA partitioning between the cytosoland ER compartments, where subsets of mRNAs encoding cytosolic/nucleoplasmicproteins are partitioned to and translated on ER-bound ribosomes(Mechler and Rabbitts, 1981; Mueckler and Pitot, 1982; Kopczynskiet al., 1998; Diehn et al., 2000, 2006; Lerner et al., 2003;Stephens et al., 2005). For example, the mRNAs encoding thekey stress response transcription factors ATF4 and XBP-1, whichare translationally silent under normal growth conditions, arehighly enriched in ER-bound small polyribosomes after activationof the UPR (Stephens et al., 2005). Extending from the datain this report, ER-directed protein synthesis may afford thecell the most efficient platform for the biogenesis of key stressresponse proteins during a cellular crisis. In addition, itmay be anticipated that nucleoplasmic regulatory proteins andtranscription factors, may be synthesized on the ER/outer nuclearenvelope. Indeed, messages encoding the mitogenic proteins cyclins-B3and -E2 have also been reported to be enriched on membrane-boundfractions; however, the biological function of such events hasyet to be determined (Diehn et al., 2006).

In studying the mechanism(s) responsible for the observed differencesin ER and cytosolic steady-state protein synthesis, similarglobal termination rates were observed in the two compartments,indicating that the kinetic advantage displayed by the ER mustreflect enhanced rates of initiation and/or elongation. Potentially,restriction of the complex, multistage reactions of proteinsynthesis to the two-dimensional plane of the ER could yieldsignificant kinetic enhancements (Berry, 2002). However, themagnitude of this effect is difficult to predict. In part, directcoupling of the tRNA deacylation reaction and protein synthesismay contribute to this relative increase in translation rate.These observations are strongly reminiscent of previous reportsdemonstrating tRNA channeling in detergent-permeabilized cells(Negrutskii and Deutscher, 1991; Stapulionis and Deutscher,1995). In these prior studies, it was observed that aminoacyltRNA deacylation/reacylation was coupled to protein synthesisand that it occurred without requisite transfer of the deacylatedtRNA to the soluble phase (Negrutskii and Deutscher, 1991; Stapulionisand Deutscher, 1995). Under the experimental conditions describedin these prior studies, the cytosol fraction was not assayed,and thus the cytosolic aminoacyl tRNA hydrolysis pathway reportedhere would not have been observed. With regard to the phenomenonof tRNA channeling, several reports have demonstrated that therelease of aminoacyl-tRNA from its cognate tRNA synthetase andthe subsequent association with elongation factor complexesare concerted events (Dang et al., 1983; Reed et al., 1994;Reed and Yang, 1994; Yang et al., 2006). Extending from datapresented here, this process may be strongly favored on theER membrane allowing for ER ribosomes to maintain a kineticadvantage in the protein synthesis reaction.

In summary, protein synthesis is a highly organized processthat likely occurs in discrete subcellular locales in whichthe assembly of translation complexes can be efficiently regulated.In this report, we have identified the ER membrane as such alocale, and we suggest that the previously observed and highlycomplex patterns of mRNA partitioning between the cytosol andER are a reflection of this organization. In this view, mRNApartitioning between the cytosol and ER serves as a novel formof posttranscriptional gene regulation, of particular relevanceto cell activation, and cell stress and recovery. Given themagnitude of the differences in the steady-state mRNA translationrates of the cytosol and ER compartments reported herein, relativelymodest alterations in cytosol/ER mRNA partitioning ratios wouldbe predicted to yield substantial differences in steady stateprotein levels. The identification of the mechanisms governingthe compartmental regulation of mRNA partitioning and the tRNAaminoacylation/deacylation cycle will provide needed insightinto the supramolecular organization of cellular protein synthesis.

ACKNOWLEDGMENTS

We thank Drs. Rebecca D. Dodd, Brook Pyhtila, Brigid Hogan,and Jon Yewdell for critical reading of the manuscript. Thiswork was supported by National Institutes of Health Grant GM-077382(to C.V.N.) and American Heart Association predoctoral fellowship0515333U (to S.B.S.).

Footnotes

This was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E07-07-0677)on December 12, 2007.

Address correspondence to: Christopher V. Nicchitta (c.nicchitta{at}cellbio.duke.edu)

Abbreviations used: ER, endoplasmic reticulum.

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