The resolution and characterization of putative ubiquitin carrier protein isozymes from rabbit reticulocytes.

The covalent ligation of the 8.6-kDa polypeptide ubiquitin to various cellular target proteins is believed to represent a fundamental regulatory process. In this mechanism, the ATP-coupled activation and subsequent ligation of ubiquitin are catalyzed by separate enzymes (E1 and E3, respectively) functionally linked by ubiquitin carrier protein (E2). Carrier protein has been proposed to constitute a family of isozymes having molecular masses of 14, 17, 20, 24, and 32 kDa whose role is to shuttle activated polypeptide in the form of a high-energy thiol ester intermediate to the carboxyl terminus of ubiquitin. Using a combination of covalent affinity and high performance liquid chromatographic methods, the pututive E2 isozymes have been purified to apparent homogeneity. The E2(14kDa) isozyme resolved into two forms differing in net charge at pH 7.5. All of the E2 isozymes contained only one thiol ester site except for E2(17kDa) and E2(20kDa) which were capable of forming two such adducts per subunit. Thiol ester formation was rapid for the E2 isozymes and required the presence of activating enzyme. In contrast, the reverse reaction of thiol ester transfer from E2 to E1 was kinetically significant for only E2(14kDa), E2(20kDa), and E2(24kDa). The stability of E2(17kDa) and E2(32kDa) to such trapping may reflect a marked shift in binding affinity to E1 upon thiol ester formation. In addition, differential rates for thiol ester formation to each subunit of dimeric E2(14kDa) was also noted. The E2(14kDa) isoforms were approximately 10-fold more active in E3-dependent ubiquitin-protein ligation than either E2(20kDa) or E2(32kDa). Neither E2(17kDa) nor E2(24kDa) supported this reaction. In addition, the thiol ester formed to E2(14kDa) was inherently more reactive since its second order rate constant for the E3-independent transfer of ubiquitin to the small molecular weight nucleophile dithiothreitol was an order of magnitude greater than found for the other isozymes. If these proteins constitute a family of isozymes, they exhibit considerable catalytic diversity.

Interferon induces a 15-kilodalton protein exhibiting marked homology to ubiquitin.

Immunochemical methods were used to examine the effect of viral infection on the dynamics of intracellular ubiquitin pools. Infection of either the human lung carcinoma line A-549 or the mouse fibroblast line L929 with encephalomyocarditis virus had little effect on either the distribution or fractional level of intracellular ubiquitin conjugates. In contrast, viral infection resulted in a significant decline in the steady state content of the mono-ubiquitin conjugate to histone 2A (uH2A). Prior treatment with interferons protected against this decrease of uH2A. Furthermore, interferons induced the de novo synthesis of a 15-kDa protein immunologically related to ubiquitin. The ubiquitin cross-reactive protein (UCRP) was not constitutively present in control cells but was significantly induced in various cells sensitive to the biological effects of interferons. Induction of UCRP with respect to both time and interferon concentration dependence closely paralleled the appearance of resistance to viral infection and could be blocked by low levels of actinomycin D. Subsequent studies demonstrated that UCRP was identical to an interferon-induced 15-kDa protein whose sequence has recently been reported (Blomstrom, D. C., Fahey, D., Kutny, R., Korant, B. D., and Knight, E. (1986) J. Biol. Chem. 261, 8811-8816). An authentic sample of the 15-kDa protein was found to co-migrate with UCRP and to cross-react with two different anti-ubiquitin antibodies. Using the authentic 15-kDa protein as a standard, UCRP accumulated to 6.2 +/- 0.5 pmol/10(6) cells and 34 +/- 2 pmol/10(6) cells in interferon-treated A-549 and L929 cultures, respectively. Comparison of the primary sequence of the 15-kDa protein to that of ubiquitin indicated that the former is composed of two domains, each of which bears striking homology to ubiquitin. These observations suggest that the 15-kDa protein may represent one example of a functionally distinct family of ubiquitin-like proteins.

The dynamics of ubiquitin pools within cultured human lung fibroblasts.

The dynamics of ubiquitin pools within the cultured human lung fibroblast line IMR-90 were examined using solid phase immunochemical methods to quantitate free and conjugated polypeptide. Fetal calf serum was found to contain a nondialyzable factor that induced a transient accumulation of ubiquitin. During the induction, free and conjugated ubiquitin pools changed in concert so that the fraction conjugated remained constant. The induction of ubiquitin by the serum factor resulted from an enhanced rate of protein synthesis. Within experimental error no change in the first order rate constant for intracellular ubiquitin degradation was observed. Pulse-chase studies revealed ubiquitin to turn over with a half-life of 28-31 h in conditioned and freshly fed cultures. Withdrawal of serum from cultures led to a rapid decline in total ubiquitin during which the fractional level of conjugation remained constant. The accelerated ubiquitin turnover following removal of serum likely involves lysosomal autophagy since 10 mM NH4Cl led to an accumulation of the polypeptide. Since no similar effect of the lysosomotropic compound was observed in conditioned or freshly fed cultures, nonlysosomal processes are probably responsible for ubiquitin turnover under nutritional balance. The dynamics of these intracellular pools suggests that the ubiquitin ligation system is subject to regulatory constraints not previously suspected. The short half-life for ubiquitin is consistent with the apparent ability of cells to alter ubiquitin levels in response to external stimuli and stress.

The immunochemical detection and quantitation of intracellular ubiquitin-protein conjugates.

ATP, ubiquitin-dependent proteolysis proceeds through covalent intermediates between target proteins destined for degradation and the 8,600-Da polypeptide ubiquitin. The ubiquitin moiety therefore represents a sensitive immunological marker for the specificity and function of this novel post-translational modification. Methods are described for the immunochemical detection of ubiquitin conjugates immobilized on nitrocellulose filters following electrophoretic transfer from sodium dodecyl sulfate-polyacrylamide gels. A further modification allows quantitation of conjugated ubiquitin to the exclusion of free polypeptide. Comparisons of conjugate pools in rabbit reticulocytes and erythrocytes demonstrate that 83 +/- 3% and 31 +/- 0.2%, respectively, of total intracellular ubiquitin exists covalently bound to target proteins. Similar large proportions of conjugated ubiquitin were found in three tissue culture cell lines. Subcellular fractionation revealed that 25% of total ubiquitin conjugates of reticulocytes sediment with the 22,000 X g stromal fraction with the remainder found in the 100,000 X g supernatant. In contrast, significant levels of erythrocyte ubiquitin conjugates occur only in the 100,000 X g supernatant, suggesting ubiquitin-mediated proteolysis actively degrades stromal components lost during terminal maturation. Reticulocytes retain their full complement of active ubiquitin during maturation indicating the concomitant decline in energy-dependent proteolysis does not result from ubiquitin inactivation. That the lower level of ubiquitin conjugates and the accompanying rate of energy-dependent proteolysis in erythrocytes is a consequence of limited substrate availability is suggested by observed increases in conjugate pools and induction of specific ubiquitin-protein adducts on incubation with either phenylhydrazine or sodium nitrite.

The inactivation of ubiquitin accounts for the inability to demonstrate ATP, ubiquitin-dependent proteolysis in liver extracts.

The low molecular weight polypeptide required for energy-dependent proteolysis, ubiquitin, is rapidly inactivated by 100,000 X g supernatants of rabbit liver extracts. Ubiquitin inactivation results from limited proteolysis by an endogenous contaminating lysosomal thiol protease having trypsin-like specificity. Evidence for this includes a pH optimum of 5.0 for the first order constant of ubiquitin inactivation and observation that inactivation is inhibited by EDTA, o-phenanthroline, iodoacetamide, p-chloromercuribenzoic acid, phenylmethylsulfonyl fluoride, N alpha-p-tosyl-L-lysine chloromethyl ketone, leupeptin, soybean trypsin inhibitor, and aprotinin. Metals stimulate but are not required for ubiquitin inactivation with the effect apparently mediated by a low molecular weight heat-labile component of crude extracts. When this heat-labile component is removed by gel exclusion chromatography a number of metals inhibit ubiquitin inactivation. In the presence of excess dithiothreitol, inhibition is relatively specific for Zn(II). Inhibition by Zn(II) is specifically overcome competitively by Cd(II) or by a concentration of ubiquitin in excess of Zn(II). The responsible cathepsin possesses a molecular mass of 35 kDa by gel exclusion chromatography and shows marked thermal lability at neutral pH but stability at acid pH. Proteolytic inactivation of ubiquitin results from limited cleavage of the carboxyl-terminal glycine dipeptide required for isopeptide bond formation and is supported by data on isoelectric point changes on subsequent digestion with carboxypeptidase B and by direct amino acid analysis. When the responsible cathepsin is inactivated, liver extracts display ATP,ubiquitin-dependent proteolysis that cannot be ascribed to contaminating erythrocytes. Thus the previous inability to demonstrate energy-dependent proteolysis in liver extracts is accounted for by the artifactual inactivation of ubiquitin.