Cloning and characterization of an androgen receptor N-terminal-interacting protein with ubiquitin-protein ligase activity.

The androgen receptor (AR) N-terminal domain plays a critical role in androgen-responsive gene regulation. A novel AR N-terminal-interacting protein (ARNIP) was isolated using the yeast two-hybrid system and its interaction with amino acids 11-172 of the normal or corresponding region of the polyglutamine-expanded human AR confirmed by glutathione S-transferase pulldown assays. ARNIP cDNAs cloned from NSC-34 (mouse neuroblastoma/spinal cord) or PC-3 (human prostate adenocarcinoma) mRNA encoded highly homologous 30 kDa (261 amino acids) cysteine-rich proteins with a RING-H2 (C3H2C3 zinc finger) domain; this motif is highly conserved in predicted ARNIP-homologous proteins from several other species. Expression of the approximately 1.7 kb ARNIP mRNA was detected in various tissues by Northern blotting, but was highest in mouse testes, kidney and several neuronal cell lines. In addition, the human ARNIP protein was found to be encoded by nine exons spanning 32 kb on chromosome 4q21. In COS-1 cells, coexpression of ARNIP and AR did not affect AR ligand-binding kinetics, nor did ARNIP act as a coactivator or corepressor in transactivation assays. However, AR N-terminal:C-terminal interaction was reduced in the presence of ARNIP. Intriguingly, ARNIP, and in particular its RING-H2 domain, functioned as a ubiquitin-protein ligase in vitro in the presence of a specific ubiquitin-conjugating enzyme, Ubc4-1. Mutation of a single cysteine residue in the ARNIP RING-H2 domain (Cys145Ala) abolished this E3 ubiquitin ligase activity. Fluorescent protein tagging studies revealed that AR-ARNIP interaction was hormone-independent in COS-1 cells, and suggest that colocalization of both AR and ARNIP to the nucleus upon androgen addition may allow ARNIP to play a role in nuclear processes. Thus, identification of a novel AR-interacting protein with ubiquitin ligase activity will stimulate further investigation into the role of ubiquitination and the ubiquitin-proteasome system in AR-mediated cellular functions.

Divergent N-terminal sequences of a deubiquitinating enzyme modulate substrate specificity.

Ubiquitin-specific processing proteases (UBPs) are characterized by a conserved core domain with surrounding divergent sequences, particularly at the N-terminal end. We previously cloned two isoforms of a testis UBP, UBP-t1 and UBP-t2, which contain identical core regions but distinct N termini that target the two isoforms to different subcellular locations (Lin, H., Keriel, A., Morales, C. R., Bedard, N., Zhao, Q., Hingamp, P., Lefrancois, S., Combaret, L., and Wing, S. S. (2000) Mol. Cell. Biol. 20, 6568-6578). To determine whether the N termini also influence the biochemical functions of the UBP, we expressed UBP-t1, UBP-t2, and the common core domain, UBP core, in Escherichia coli. The three isoforms cleaved branched triubiquitin at >20-fold faster rates than linear diubiquitin, suggesting that UBP-testis functions as an isopeptidase. Both N-terminal extensions inhibited the ability of UBP-core to generate free ubiquitin when linked in a peptide bond with itself, another peptide, or to small adducts. The N-terminal extension of UBP-t2 increased the ability of UBP-core to cleave branched triubiquitin. UBP-core removed ubiquitin from testis ubiquitinated proteins more rapidly than UBP-t2 and UBP-t1. Thus, UBP enzymes appear to contain a catalytic core domain, the activities and specificities of which can be modulated by N-terminal extensions. These divergent N termini can alter localization and confer multiple functions to the various members of the large UBP family.

Divergent N-terminal sequences target an inducible testis deubiquitinating enzyme to distinct subcellular structures.

Ubiquitin-specific processing proteases (UBPs) presently form the largest enzyme family in the ubiquitin system, characterized by a core region containing conserved motifs surrounded by divergent sequences, most commonly at the N-terminal end. The functions of these divergent sequences remain unclear. We identified two isoforms of a novel testis-specific UBP, UBP-t1 and UBP-t2, which contain identical core regions but distinct N termini, thereby permitting dissection of the functions of these two regions. Both isoforms were germ cell specific and developmentally regulated. Immunocytochemistry revealed that UBP-t1 was induced in step 16 to 19 spermatids while UBP-t2 was expressed in step 18 to 19 spermatids. Immunoelectron microscopy showed that UBP-t1 was found in the nucleus while UBP-t2 was extranuclear and was found in residual bodies. For the first time, we show that the differential subcellular localization was due to the distinct N-terminal sequences. When transfected into COS-7 cells, the core region was expressed throughout the cell but the UBP-t1 and UBP-t2 isoforms were concentrated in the nucleus and the perinuclear region, respectively. Fusions of each N-terminal end with green fluorescent protein yielded the same subcellular localization as the native proteins, indicating that the N-terminal ends were sufficient for determining differential localization. Interestingly, UBP-t2 colocalized with anti-gamma-tubulin immunoreactivity, indicating that like several other components of the ubiquitin system, a deubiquitinating enzyme is associated with the centrosome. Regulated expression and alternative N termini can confer specificity of UBP function by restricting its temporal and spatial loci of action.

The tyrosine kinase negative regulator c-Cbl as a RING-type, E2-dependent ubiquitin-protein ligase.

Ubiquitination of receptor protein-tyrosine kinases (RPTKs) terminates signaling by marking active receptors for degradation. c-Cbl, an adapter protein for RPTKs, positively regulates RPTK ubiquitination in a manner dependent on its variant SRC homology 2 (SH2) and RING finger domains. Ubiquitin-protein ligases (or E3s) are the components of ubiquitination pathways that recognize target substrates and promote their ligation to ubiquitin. The c-Cbl protein acted as an E3 that can recognize tyrosine-phosphorylated substrates, such as the activated platelet-derived growth factor receptor, through its SH2 domain and that recruits and allosterically activates an E2 ubiquitin-conjugating enzyme through its RING domain. These results reveal an SH2-containing protein that functions as a ubiquitin-protein ligase and thus provide a distinct mechanism for substrate targeting in the ubiquitin system.

Activation of a UBC4-dependent pathway of ubiquitin conjugation during postnatal development of the rat testis.

During spermatogenesis, germ cells undergo mitotic and meiotic divisions to form haploid round spermatids which mature to functional elongated spermatozoa. During this process there occurs remodeling of cell structure and loss of most of the cytoplasm and a large fraction of cellular proteins. To evaluate the role of the ubiquitin proteolytic system in this protein loss, we measured levels of ubiquitinated proteins and rates of ubiquitin conjugation in extracts of testes from rats of different ages. Endogenous ubiquitin-protein conjugates increased till day 30 and then reached a plateau. In parallel, there was a progressive increase in the rate of conjugation of ubiquitin to proteins in testis extracts from these animals. To test the importance of two major ubiquitin conjugating enzyme families in the conjugation, immunoprecipitation of UBC2 or UBC4 from 10- and 30-day-old testis extracts was carried out and the remaining conjugation activity in supernatants was assayed. Depletion of either enzyme family resulted in decreased conjugation. However, most of the conjugation activity and, more importantly, the increased conjugation during development were UBC4-dependent. Immunocytochemistry demonstrated a marked increase in expression of UBC4 in spermatids, consistent with the UBC4-dependent activation of conjugation seen in vitro. In situ hybridization studies evaluated the contribution of various UBC4 isoforms to this induction. UBC4-1 mRNA was expressed in most cells. UBC4-2 mRNA was restricted to germ cells with high levels of expression in round and elongated spermatids. UBC4-testis had previously been shown to be expressed only in spermatids. Our data suggest that induction of various UBC4 isoforms activates overall conjugation and plays an important role in the cellular remodeling and protein loss occurring during spermatogenesis.

Identification of rabbit reticulocyte E217K as a UBC7 homologue and functional characterization of its core domain loop.

The structural basis by which ubiquitin (Ub)-conjugating enzymes (E2s) determine substrate specificity remains unclear. We cloned rabbit reticulocyte E217K because unlike the similarly sized class I E2s, E214K and UBC4, it is unable to support ubiquitin-protein ligase (E3)-dependent conjugation to endogenous proteins. RNA analysis revealed that this E2 was expressed in all tissues tested, with higher levels in the testis. Analysis of testis RNA from rats of different ages showed that E217K mRNA was induced from days 15 to 30. The predicted amino acid sequence indicates that E217K is a 19. 5-kDa class I E2 but differs from other class I enzymes in possessing an insertion of 13 amino acids distal to the active site cysteine. E217K shows 74% amino acid identity with Saccharomyces cerevisiae UBC7, and therefore, we rename it mammalian UBC7. Yeast UBC7 crystal structure indicates that this insertion forms a loop out of the otherwise conserved folding structure. Sequence analysis of E2s had previously suggested that this loop is a hypervariable region and may play a role in substrate specificity. We created mutant UBC7 lacking the loop (ubc7Deltaloop) and a mutant E214k with an inserted loop (E214k+loop) and characterized their biochemical functions. Ubc7Deltaloop had higher affinity for the E1-Ub thiol ester than native UBC7 and permitted conjugation of Ub to selected proteins in the testis but did not permit the broad spectrum E3-dependent conjugation to endogenous reticulocyte proteins. Surprisingly, E214k+loop was unable to accept Ub from ubiquitin-activating enzyme (E1) but was able to accept NEDD8 from E1. E214k+loop was able to support conjugation of NEDD8 to endogenous reticulocyte proteins but with much lower efficiency than E214k. Thus, the loop can influence interactions of the E2 with charged E1 as well as with E3s or substrates, but the exact nature of these interactions depends on divergent sequences in the remaining conserved core domain.

Identification of amino acid residues in a class I ubiquitin-conjugating enzyme involved in determining specificity of conjugation of ubiquitin to proteins.

The ubiquitin pathway is a major system for selective proteolysis in eukaryotes. However, the mechanisms underlying substrate selectivity by the ubiquitin system remain unclear. We previously identified isoforms of a rat ubiquitin-conjugating enzyme (E2) homologous to the Saccharomyces cerevisiae class I E2 genes, UBC4/UBC5. Two isoforms, although 93% identical, show distinct features. UBC4-1 is expressed ubiquitously, whereas UBC4-testis is expressed in spermatids. Interestingly, although these isoforms interacted similarly with some ubiquitin-protein ligases (E3s) such as E6-AP and rat p100 and an E3 that conjugates ubiquitin to histone H2A, they also supported conjugation of ubiquitin to distinct subsets of testis proteins. UBC4-1 showed an 11-fold greater ability to support conjugation of ubiquitin to endogenous substrates present in a testis nuclear fraction. Site-directed mutagenesis of the UBC4-testis isoform was undertaken to identify regions of the molecule responsible for the observed difference in substrate specificity. Four residues (Gln-15, Ala-49, Ser-107, and Gln-125) scattered on surfaces away from the active site appeared necessary and sufficient for UBC4-1-like conjugation. These four residues identify a large surface of the E2 core domain that may represent an area of binding to E3s or substrates. These findings demonstrate that a limited number of amino acid substitutions in E2s can dictate conjugation of ubiquitin to different proteins and indicate a mechanism by which small E2 molecules can encode a wide range of substrate specificities.

Insulin-like growth factor I stimulates degradation of an mRNA transcript encoding the 14 kDa ubiquitin-conjugating enzyme.

Upon fasting, the ubiquitin-dependent proteolytic system is activated in skeletal muscle in parallel with the increases in rates of proteolysis. Levels of mRNA encoding the 14 kDa ubiquitin-conjugating enzyme (E2(14K)), which can catalyse the first irreversible reaction in this pathway, rise and fall in parallel with the rates of proteolysis [Wing and Banville (1994) Am.J. Physiol. 267, E39-E48], indicating that the conjugation of ubiquitin to proteins is a regulated step. To characterize the mechanisms of this regulation, we have examined the effects of insulin, insulin-like growth factor I (IGF-I) and des(1-3) insulin-like growth factor I (DES-IGF-I), which does not bind IGF-binding proteins, on E2(14K) mRNA levels in L6 myotubes. Insulin suppressed levels of E2(14K) mRNA with an IC50 of 4 x 10(-9) M, but had no effects on mRNAs encoding polyubiquitin and proteasome subunits C2 and C8, which, like E2(14K), also increase in skeletal muscle upon fasting. Reduction of E2(14K) mRNA levels was more sensitive to IGF-I with an IC50 of approx. 5 x 10(-10) M. During the incubation of these cells for 12 h there was significant secretion of IGF-I-binding proteins into the medium. DES-IGF-I, which has markedly reduced affinity for these binding proteins, was found to potently reduce E2(14K) mRNA levels with an IC50 of 3 x 10(-11) M. DES-IGF-I did not alter rates of transcription of the E2(14K) gene, but enhanced the rate of degradation of the 1.2 kb mRNA transcript. The half-life of the 1.2 kb transcript was approximately one-third that of the 1.8 kb transcript and can explain the more marked regulation of this transcript observed previously. This indicates that the additional 3' non-coding sequence in the 1.8 kb transcript confers stability. These observations suggest that IGF-I is an important regulator of E2(14K) expression and demonstrate, for the first time, stimulation of degradation of a specific mRNA transcript by this hormone, while overall RNA accumulates.

A novel rat homolog of the Saccharomyces cerevisiae ubiquitin-conjugating enzymes UBC4 and UBC5 with distinct biochemical features is induced during spermatogenesis.

The Saccharomyces cerevisiae ubiquitin-conjugating enzymes (E2s) UBC4 and UBC5 are essential for degradation of short-lived and abnormal proteins. We previously identified rat cDNAs encoding two E2s with strong sequence similarity to UBC4 and UBC5. These E2 isoforms are widely expressed in rat tissues, consistent with a fundamental cellular function for these E2s. We now report a new isoform, 8A, which despite having >91% amino acid identity with the other isoforms, shows several novel features. Expression of the 8A isoform appears restricted to the testis, is absent in early life, but is induced during puberty. Hypophysectomy reduced expression of the 8A isoform. In situ hybridization studies indicated that 8A mRNA is expressed mainly in round spermatids. Immunoblot analyses showed that 8A protein is found not only in subfractions of germ cells enriched in round spermatids but also in subfractions containing residual bodies extruded from more mature elongated spermatids, indicating that the protein possesses a longer half-life than the mRNA. Unlike all previously identified mammalian and plant homologs of S. cerevisiae UBC4, which possess a basic pI, the 8A isoform is unique in possessing an acidic pI. The small differences in sequence between the 8A isoform and other rat isoforms conferred differences in biochemical function. The 8A isoform was less effective than an isoform with a basic pI or ineffective in conjugating ubiquitin to certain fractions of testis proteins. Thus, although multiple isoforms of a specific E2 may exist to ensure performance of a critical cellular function, our data demonstrate, for the first time, that multiple genes also permit highly specialized regulation of expression of specific isoforms and that subtle differences in E2 primary structure can dictate conjugation of ubiquitin to different subsets of cellular proteins.

Increase in levels of polyubiquitin and proteasome mRNA in skeletal muscle during starvation and denervation atrophy.

Most of the increased protein degradation in muscle atrophy caused by starvation and denervation is due to activation of a non-lysosomal ATP-dependent proteolytic process. To determine whether expression of the ubiquitin-proteasome-dependent pathway is activated in atrophying muscles, we measured the levels of mRNA for ubiquitin (Ub) and proteasome subunits, and Ub content. After rats had been deprived of food for 1 or 2 days, the concentration of the two polyubiquitin (polyUb) transcripts increased 2-4-fold in the pale extensor digitorum longus muscle and 1-2.5-fold in the red soleus, whereas total muscle RNA and total mRNA content fell by 50%. After denervation of the soleus, there was a progressive 2-3-fold increase in polyUb mRNA for 1-3 days, whereas total RNA content fell. On starvation or denervation, Ub concentration in the muscles also rose by 60-90%. During starvation, polyUb mRNA levels also increased in heart, but not in liver, kidney, spleen, fat, brain or testes. Although the polyUb gene is a heat-shock gene that is induced in muscles under certain stressful conditions, the muscles of starving rats or after denervation did not express other heat-shock genes. On starvation or denervation, mRNA for several proteasome subunits (C-1, C-3, C-5, C-8 and C-9) also increased 2-4-fold in the atrophying muscles. When the food-deprived animals were re-fed, levels of Ub and proteasome mRNA in their muscles returned to control values within 1 day. In contrast, no change occurred in the levels of muscle mRNAs encoding cathepsin L, cathepsin D and calpain 1 on denervation or food deprivation. Thus polyUb and proteasome mRNAs increased in atrophying muscles in co-ordination with activation of the ATP-dependent proteolytic process.

Increase in ubiquitin-protein conjugates concomitant with the increase in proteolysis in rat skeletal muscle during starvation and atrophy denervation.

The rapid loss of skeletal-muscle protein during starvation and after denervation occurs primarily through increased rates of protein breakdown and activation of a non-lysosomal ATP-dependent proteolytic process. To investigate whether protein flux through the ubiquitin (Ub)-proteasome pathway is enhanced, as was suggested by related studies, we measured, using specific polyclonal antibodies, the levels of Ub-conjugated proteins in normal and atrophying muscles. The content of these critical intermediates had increased 50-250% after food deprivation in the extensor digitorum longus and soleus muscles 2 days after denervation. Like rates of proteolysis, the amount of Ub-protein conjugates and the fraction of Ub conjugated to proteins increased progressively during food deprivation and returned to normal within 1 day of refeeding. During starvation, muscles of adrenalectomized rats failed to increase protein breakdown, and they showed 50% lower levels of Ub-protein conjugates than those of starved control animals. The changes in the pools of Ub-conjugated proteins (the substrates for the 26S proteasome) thus coincided with and can account for the alterations in overall proteolysis. In this pathway, large multiubiquitinated proteins are preferentially degraded, and the Ub-protein conjugates that accumulated in atrophying muscles were of high molecular mass (> 100 kDa). When innervated and denervated gastrocnemius muscles were fractionated, a significant increase in ubiquitinated proteins was found in the myofibrillar fraction, the proteins of which are preferentially degraded on denervation, but not in the soluble fraction. Thus activation of this proteolytic pathway in atrophying muscles probably occurs initially by increasing Ub conjugation to cell proteins. The resulting accumulation of Ub-protein conjugates suggests that their degradation by the 26S proteasome complex subsequently becomes rate-limiting in these catabolic states.

Molecular cloning, expression and characterization of a ubiquitin conjugation enzyme (E2(17)kB) highly expressed in rat testis.

Ubiquitin-conjugating enzymes (E2s) play a key role in ubiquitin-mediated proteolysis by catalysing the conjugation of ubiquitin to protein substrates. We have previously reported the cDNA cloning of a 14 kDa conjugating enzyme [E2(14)k; Wing, Dumas and Banville (1992) J. Biol. Chem. 267, 6495-6501] that efficiently supported ubiquitination and protein degradation in reticulocyte extracts. Surprisingly, the structure of this E2 was markedly more similar to the Saccharomyces cerevisiae DNA repair gene RAD6, than to the S. cerevisiae UBC4/UBC5 genes which are required for the degradation of short-lived proteins and support much of the ubiquitination of yeast proteins. This suggested that mammalian homologues of UBC4/UBC5 remained to be identified. Using oligonucleotides derived from the S. cerevisiae UBC4 sequence as primers in a PCR reaction with rat muscle cDNA as a template, a 390 bp DNA fragment was amplified which predicted an amino acid sequence that was 83% identical to yeast UBC4. Screening a rat testes cDNA library identified a family of cDNAs which predicted two very similar proteins with basic pIs and molecular masses of approx. 16,700 Da. Isoform 2E was expressed in Escherichia coli and purified to homogeneity. It supported ubiquitination to reticulocyte and testis proteins more rapidly in vitro and produced larger conjugates than E2(14)k. Examination of RNA from different tissues indicated that this type of E2 was expressed in a broad spectrum of tissues but at particularly high levels in the testis. Fractionation of a testis extract by anion-exchange chromatography identified several putative ubiquitin protein ligase activities with which this E2 could interact in promoting conjugation of ubiquitin to proteins. One of these activities supported conjugation of ubiquitin to histone H2A, a substrate degraded in the ubiquitin system by a non-N-end rule mechanism. This paper reports the first cloning of a apparent mammalian homologue of S. cerevisiae UBC4/UBC5. Its high expression in testis and ability to efficiently support conjugation to testis proteins suggest that this family of E2s may play a role in the proteolysis that occurs during spermatogenesis.

14-kDa ubiquitin-conjugating enzyme: structure of the rat gene and regulation upon fasting and by insulin.

Upon fasting, an increase in proteolysis occurs in rat skeletal muscle and is associated with increased levels of ubiquitin-protein conjugates. As this suggests that formation of conjugates may be activated upon fasting, we studied the expression of the gene encoding the 14-kDa ubiquitin-conjugating enzyme (E2(14k)). A cDNA encoding rat E2(14k) was isolated and used to probe Northern blots of RNA from extensor digitorum longus muscles of fed, fasted, and refed rats. Two mRNA transcripts of 1.2 and 1.8 kb were observed. Isolation and sequencing of a genomic clone determined that these transcripts arise from differential sites of polyadenylation. The 1.2-kb transcript increased threefold upon fasting at 2 days and returned to normal with refeeding. Northern analysis of RNA from various tissues of fed and fasted rats showed that E2(14k) mRNA was expressed at high levels in testes, moderate levels in muscle, heart, and brain, but low levels in liver and kidney. Upon fasting, increases in mRNA levels were seen in muscle, heart, liver, and kidney. In vitro, in rat L6 myotubes, insulin lowered levels of E2(14k) mRNA. Because E2s catalyze the first irreversible reaction in the pathway and E2(14k) gene expression appears to change in parallel with the changes in levels of ubiquitinated proteins and rates of proteolysis, conjugation mediated by this E2 may be a rate-limiting step in the pathway. This is the first demonstration of direct hormonal regulation of a gene in the ubiquitin system and argues strongly for a role of the ubiquitin system in the metabolic response to fasting in skeletal muscle.

Glucocorticoids activate the ATP-ubiquitin-dependent proteolytic system in skeletal muscle during fasting.

Glucocorticoids are essential for the increase in protein breakdown in skeletal muscle normally seen during fasting. To determine which proteolytic pathway(s) are activated upon fasting, leg muscles from fed and fasted normal rats were incubated under conditions that block or activate different proteolytic systems. After food deprivation (1 day), the nonlysosomal ATP-dependent process increased by 250%, as shown in experiments involving depletion of muscle ATP. Also, the maximal capacity of the lysosomal process increased 60-100%, but no changes occurred in the Ca(2+)-dependent or the residual energy-independent proteolytic processes. In muscles from fasted normal and adrenalectomized (ADX) rats, the protein breakdown sensitive to inhibitors of the lysosomal or Ca(2+)-dependent pathways did not differ. However, the ATP-dependent process was 30% slower in muscles from fasted ADX rats. Administering dexamethasone to these animals or incubating their muscles with dexamethasone reversed this defect. During fasting, when the ATP-dependent process rises, muscles show a two- to threefold increase in levels of ubiquitin (Ub) mRNA. However, muscles of ADX animals failed to show this response. Injecting dexamethasone into the fasted ADX animals increased muscle Ub mRNA within 6 h. Thus glucocorticoids activate the ATP-Ub-dependent proteolytic pathway in fasting apparently by enhancing the expression of components of this system such as Ub.

A rabbit reticulocyte ubiquitin carrier protein that supports ubiquitin-dependent proteolysis (E214k) is homologous to the yeast DNA repair gene RAD6.

The two isoforms of the 14-kDa ubiquitin carrier protein (E2(14k)) are unique among rabbit E2s in efficiently supporting ubiquitin-protein ligase (E3)-mediated ubiquitination of proteins destined for degradation. To begin determining the structural basis for this property, we have isolated a cDNA encoding the predominant reticulocyte isoform of the E2 from a rabbit skeletal muscle library. The sequence predicts a protein of 152 amino acids with a molecular weight of 17,293. Expression of the cDNA in Escherichia coli and purification of the recombinant protein revealed an E2 with high affinity for E3 and ubiquitin activating enzyme (E1). The latter high affinity interaction appears to be between the ubiquitin charged form of E1 and the uncharged form of E2 and does not result in a stable complex between these two enzymes. The predicted sequence shows regions of strong homology with other sequenced E2s, suggesting that these regions may be involved in binding to E1 and/or in ubiquitin transfer from E1, functions common to all E2s. Surprisingly, the E2(14k)) sequence is markedly more similar to Saccharomyces cerevisiae RAD6 (69% identity) than to its proposed homologs UBC4/UBC5 (38% identity). The sequence is identical to that recently reported for a human 17-kDa E2 which can complement rad6 mutants thereby identifying rabbit E2(14k) as a RAD6 homologue. The biochemical properties of this previously uncharacterized human 17-kDa E2 are now defined and its misassignment as a homologue of rabbit E2(17k) is corrected. Our findings resolve current confusion regarding relationships among E2s and define yeast RAD6, rabbit E2(14k), and the human 17-kDa E2 as a subclass of E2s which biochemically support E3-mediated conjugation and ubiquitin-dependent proteolysis and physiologically play a role in DNA repair.

Proteins containing peptide sequences related to Lys-Phe-Glu-Arg-Gln are selectively depleted in liver and heart, but not skeletal muscle, of fasted rats.

In response to serum withdrawal, when overall rates of proteolysis increase in cultured fibroblasts, proteins containing peptide regions similar to Lys-Phe-Gln-Arg-Gln (KFERQ) are targeted to lysosomes for degradation, and the intracellular concentrations of these proteins decline [Chiang & Dice (1988) J. Biol. Chem. 263, 6797-6805]. To test whether such proteins are also selectively depleted in mammalian tissues in vivo, we have used affinity-purified polyclonal antibodies to KFERQ to detect proteins containing such sequences in tissues of fed and fasted rats. Immunoreactive cytosolic proteins were partially depleted from liver and heart of fasted rats, but the time course differed for these two tissues. Immunoreactive proteins in liver were lost during days 2 and 3 of fasting, whereas such proteins in heart were depleted within day 1 of fasting. In the same fasted rats, levels of immunoreactive cytosolic proteins did not change in two skeletal muscles, the dark soleus and the pale extensor digitorum longus. Immunoreactive proteins in a myofibrillar fraction were also partially depleted in heart, but not in skeletal muscles, of fasted rats. The most likely explanation for these results is that the protein loss in different tissues upon fasting results from selective activation of different proteolytic pathways. The increased proteolysis in liver and heart of fasted animals includes activation of the KFERQ-selective lysosomal pathway, whereas increased proteolysis in skeletal muscle does not.

Activation of the ubiquitin-ATP-dependent proteolytic system in skeletal muscle during fasting and denervation atrophy.

The rapid atrophy of skeletal muscles upon fasting or denervation is due largely to an increased rate of protein breakdown. Blocking the lysosomal or the Ca(2+)-dependent pathways did not prevent increased proteolysis in muscles from fasted animals or following denervation. In contrast, upon food deprivation, the nonlysosomal ATP-dependent process increased by 150-350%. After refeeding, this process returned to control levels by 24 h. Similarly, within one day after denervation of the soleus, proteolysis increased by 50-250%. By contrast, the residual energy-independent process did not change in fasting or denervation. Because the ATP-dependent process might involve activation of the ubiquitin-ATP-dependent pathway, we measured the levels of mRNA for ubiquitin [Ub] in the atrophying muscles. After food deprivation, the levels of polyUb transcripts increased 2- to 4-fold in the soleus and extensor digitorum longus (EDL) muscles, and returned to control levels within 1 day of refeeding. After denervation of the soleus, a 2- to 3-fold increase in polyUb mRNA also occurred within 1 day. The muscle content of ubiquitinated protein also changed in parallel with Ub mRNA levels under these conditions. Thus, polyUb genes appear to be selectively induced in atrophying muscle, and levels of Ub mRNA and ubiquitin-protein conjugates change coordinately with the rate of ATP-dependent proteolysis. These data suggest that in atrophying muscle the ATP-Ub-dependent system plays an important physiological role in the degradation of the bulk of cell proteins.

Adverse immunologic effects of antithyroid drugs.

Propylthiouracil and methimazole are frequently used in the management of hyperthyroidism. Two patients in whom adverse immunologic effects other than isolated agranulocytosis developed during treatment with propylthiouracil are described. A review of the literature revealed 53 similar cases over a 35-year period. Rash, fever, arthralgias and granulocytopenia were the most common manifestations. Vasculitis, particularly with cutaneous manifestations, occurs and may be fatal. The clinical evidence suggests that an immunologic mechanism is involved. A number of different autoantibodies were reported, but antinuclear antibodies were infrequent, and none of the cases met the criteria for a diagnosis of systemic lupus erythematosus. Thus, the reactions do not represent a true drug-induced lupus syndrome. Current hypotheses and experimental data regarding the cause of the reactions are reviewed. No specific clinical subgroup at high risk can be identified, and manifestations may occur at any dosage and at any time during therapy. Cross-reactivity between the two antithyroid drugs can be expected. Except for minor symptoms (e.g., mild arthralgias or transient rash), such reactions are an indication for withdrawal of the drug and the use of alternative methods to control the hyperthyroidism. In rare cases of severe vasculitis a short course of high-dose glucocorticoid therapy may be helpful.

Purification and properties of a NAD(P)H:flavin oxidoreductase from the luminous bacterium, Beneckea harveyi.

A NAD(P)H:flavin oxidoreductase, which produces FMNH2, one of the substrates for the luciferase reaction in bioluminescent bacteria, has been purified with the aid of affinity chromatography on epsilon-aminohexanoyl-FMN-Sepharose. The purified enzyme, isolated from Beneckea harveyi, had a specific activity of 89 mumol of NADH oxidized/min/mg of protein at 23 degrees in the presence of saturating FMN and NADH and appeared homogeneous by several criteria on polyacrylamide gel electrophoresis. A molecular weight of 24,000 was estimated both by gel filtration and and sodium dodecyl sulfate gel electrophoresis indicating that the enzyme is composed of a single polypeptide chain. Kinetic studies showed that the higher specificity of the enzyme for NADH than NADPH and for riboflavin and FMN than FAD was primarily due to variations in the Michaelis constants for the different substrates. Initial velocity studies with all pairs of substrates gave intersecting patterns supporting a sequential mechanism for the NAD(P)H:flavin oxidoreductase.