Altered Processing of Pro-Orphanin FQ/Nociceptin and Pro-Opiomelanocortin-Derived Peptides in the Brains of Mice Expressing Defective Prohormone Convertase 2

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The Journal of Neuroscience, August 15, 2001, 21(16):5864-5870

Altered Processing of Pro-Orphanin FQ/Nociceptin and Pro-Opiomelanocortin-Derived Peptides in the Brains of Mice Expressing Defective Prohormone Convertase 2
Richard G. Allen², Bonnie Peng¹, Michael J. Pellegrino², Emilie D. Miller³, David K. Grandy⁴, James R. Lundblad⁵, Carrie L. Washburn², and John E. Pintar¹
¹ Neuroscience and Cell Biology, University of Medicine and Dentistry of New Jersey-Robert Wood Johnson Medical School, Piscataway, New Jersey 08854, and ² Center for Research on Occupational and Environmental Toxicology, ³ Neuroscience Graduate Program, and Departments of ⁴ Physiology and Pharmacology and ⁵ Molecular Medicine, Oregon Health Sciences University, Portland, Oregon 97201

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The bioactivity of neuropeptides can be regulated by a variety of post-translational modifications, including proteolyticprocessing. Here, gene-targeted mice producing defective prohormoneconvertase 2 (PC2) were used to examine the post-translationalprocessing of two neuroendocrine prohormones, pro-opiomelanocortin(POMC) and pro-orphanin FQ (pOFQ)/nociceptin (N), in the brain.Reversed-phase HPLC and gel-exclusion chromatography were combinedwith specific radioimmunoassays to analyze the processing patternsof these two prohormones in the hypothalamus and the amygdala.In the case of POMC, the lack of PC2 activity completely preventedcarboxy-shortening of $beta$ -endorphins and greatly diminished conversionof $beta$ -lipotropin to $gamma$ -lipotropin and $beta$ -endorphin. Although conversionof $beta$ -lipotropin to $beta$ -endorphin decreased, the lack of PC2 activitycaused an increase in $beta$ -lipotropin and $beta$ -endorphin levels in themutant animals, but no increases in POMC or biosynthetic intermediateswere seen. The extent of OFQ/N production was significantly lowerin PC2-deficient mice and there was an accumulation of relativelylarge amounts of pOFQ/N and biosynthetic intermediates. Theseresults demonstrate that PC2 is directly involved in the biogenesisof two brain neuropeptides in vivo and suggest that the specificprohormone and cellular context influences neuropeptide processingbyPCs.

Key words: neuropeptide; proteolytic processing; pro-orphanin FQ/nociceptin; POMC; PC2; gene-targeting

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neuropeptides are generated from inactive precursors by proteolytic processing and concentrated into large, dense core vesiclesfor release (Sossin et al., 1989). Two members of the subtilisin-likeprohormone convertase (PC) family, PC2 and PC1/PC3 (PC1), playmajor roles in neuroendocrine precursor processing and appearto provide the basis for the tissue-specific aspects of proteolyticpeptide processing (Rouille et al., 1995). PC1 and PC2 are expressedexclusively in the brain and neuroendocrine systems, whereas othermembers of this family are expressed more ubiquitously (Rouilleet al., 1995; Zhou et al., 1999).

Over the last two decades, the tissue-specific, proteolytic processing of the neuroendocrine prohormone pro-opiomelanocortin(POMC) has been studied in great detail, particularly in the pituitarygland, and has been found to be correlated with PC expression(Mains et al., 1977; Eipper and Mains, 1980; Mains and Eipper,1981; Rouille et al., 1995). These studies have shown that PC1is expressed at high levels in the anterior lobe of the pituitarygland, whereas both PC2 and PC1 are expressed in the intermediatelobe (Day et al., 1992; Seidah and Chretien, 1992). PC2 is believedto be responsible for the additional cleavages of POMC-derivedpeptides found in the intermediate pituitary (Rouille et al.,1995). POMC processing has also been studied in the rat hypothalamus,and the extent of proteolytic processing is similar to the POMCpeptide processing patterns found in the neurointermediate pituitary(Emeson and Eipper, 1986). The hallmarks of this proteolytic processingare the essentially complete conversion of $beta$ -lipotropin ( $beta$ -LPH)to $gamma$ -LPH and $beta$ -endorphin and the subsequent carboxy-shorteningof approximately one-third of the $beta$ -endorphin 1-31 molecules to $beta$ -endorphin 1-27 and 1-26. Figure 1A summarizes the general proteolyticprocessing patterns of the $beta$ -LPH- $beta$ -endorphin domain in the rathypothalamus.

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Figure 1. A, C-terminal proteolytic processing of pre-POMC (pPOMC). A schematic representation of the $beta$ -LPH- $beta$ -endorphin processing pathway in the rodent hypothalamus. B, A schematic representation of ppOFQ/N processing in the rodent hypothalamus. Predicted and potential cleavages by PC1and PC2 based on pituitary POMC processing are indicated. The processing patterns shown are thought to occur in mice expressing WT PC2. K, Lysine; R, arginine. Asterisks denote potential paired basic cleavages in OFQ/N. Arrows denote PC cleavage sites.

Prepro-orphanin FQ (ppOFQ)/nociceptin (N) is a prohormone encoding the neuropeptide OFQ/N, as well as other potential peptides(Bunzow et al., 1994; Meunier et al., 1995; Reinscheid et al.,1995). OFQ/N and its receptor (ORL₁) are expressed abundantlyin the brain and spinal cord (Houtani et al., 2000) and have beenimplicated in a variety of physiological processes, such as cellexcitability (Vaughan et al., 1997; Yu et al., 1997; Pan et al.,2000) and cAMP production (Reinscheid et al., 1995); they alsopossess nociceptive and anxiolytic properties (Jenck et al., 1997;Koster et al., 1999). Relatively little is known about pOFQ/Nprocessing or the role of the PCs in the generation of individualneuropeptides from the proprotein, although we have shown previouslythat the major OFQ/N-containing peptide produced in the rat, mouse,and monkey hypothalamus is OFQ/N1-17 (Quigley et al., 1998). Figure1B summarizes what is known about pOFQ/N proteolyticprocessing.

Mice lacking an active PC2 exhibit defective hormone processing in the proinsulin, proglucagon, and prosomatostatin systemsof the pancreas (Furuta et al., 1997). In the present study, wehave used these mice to examine the effects of PC2 deficiencyon the processing of two neuroendocrine precursors in specificbrain tissues (Fig. 1). Here we use radioimmunoassays (RIAs) forPOMC-derived peptides [ $beta$ -endorphin and $beta$ -melanocyte-stimulatinghormone ( $beta$ -MSH)] and for OFQ/N, combined with biochemical fractionationmethods, to show that lack of a functional PC2 affects both rateand site-specific proteolytic cleavages of pOFQ/nociceptin andPOMC-derived peptides in a proprotein-specificmanner.

  MATERIALS AND METHODS

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INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. All +/+ and PC2-deficient $-$ / $-$ mice bred were littermates obtained from the mating of PC2 +/ $-$ mice initially providedby Dr. D. Steiner (Howard Hughes Medical Institute, Universityof Chicago, Chicago, IL). The PC2-deficient mice contain an insertionof a neomycin cassette into exon 3 of the PC2 gene (Furuta etal., 1997). This insertion alters transcript splicing and preventsactivation of the mutated PC2 precursor. Homozygous $-$ / $-$ mice thuslack any PC2 activity. All animals were housed and used accordingto institutional guidelines prescribed by the National InstitutesofHealth.

Tissue isolation and sample preparation. Individual hypothalamic and amygdala tissues from wild-type (WT), heterozygous, andhomozygous mutant mice were extracted in 0.5 ml of 10% aceticacid containing 0.5 mg/ml bovine serum albumin (BSA) and proteaseinhibitors (1 µl/ml protease inhibitor cocktail; Sigma, St. Louis,MO). Samples were homogenized manually and then frozen and thawedthree times. Tissue extracts were centrifuged, and the supernatantswere lyophilized for peptideanalyses.

Reversed-phase HPLC. After lyophilization, tissue extracts were resuspended in 500 µl of trifluoroacetic acid (TFA) and injectedonto a Vydac (214TP54) RP-HPLC column (C4, 300 Å pore size; TheSeparations Group, Hesperia, CA). The extracts were fractionatedusing a Waters (Milford, NJ) reversed phase (RP)-HPLC system withlinear gradients of acetonitrile in 0.1% TFA and a flow rate of1 ml/min. Generally, 80 1-min fractions were collected using agradient of 8-36% acetonitrile. An additional gradient startingwith 13.6% acetonitrile for 3 min, a step-up to 17.6% acetonitrilein 2 min, and then a linear gradient to 36% acetonitrile at 80min was used for some POMC peptide fractionations. Aliquots werethen vacuum dried before RIA. In some cases, an additional isocraticelution at 36% acetonitrile, after the linear gradient, was usedto elutePOMC.

Gel-exclusion chromatography. Lyophilized extracts were resuspended in 0.5 ml of 3 M acetic acid and injected onto a 1 × 35cm column (Bio-Rad, Richmond, CA) of Sephadex G-50 (Pharmacia,Piscataway, NJ) using 3 M acetic acid containing 10 µg/mg BSAto elute the peptides by FPLC (Pharmacia). The flow rate was 1ml/min, and 1 min fractions were collected. Molecular weight markersare shown in thefigures.

RIA. The OFQ/N antiserum is specific to the C terminus of OFQ/N1-17 and does not cross-react with $beta$ -endorphin or dynorphin(DYN) A. Tyr14 OFQ/nociceptin was iodinated using the chloramine-Tmethod (Quigley et al., 1998). The $beta$ -endorphin and $beta$ -MSH RIAshave been described previously (Hatfield et al., 1988). The $beta$ -endorphinantiserum is specific to the mid-portion of $beta$ -endorphin 1-31 andcross-reacts 1:1 with all $beta$ -endorphins and $beta$ -LPH (Hatfield etal., 1988). The $beta$ -MSH antiserum is specific to the mid-portionof $beta$ -MSH and cross-reacts with the C terminus of $gamma$ -LPH (Hatfieldet al., 1988; Thorne and Thomas, 1990). An antiserum specificfor mouse (m)ppOFQ/N160-187 was generated in rabbits against thesynthesized peptide after conjugation by Covance (Denver, PA).This antiserum (VO61) was used at a final dilution of 1:3000 anddoes not cross-react with OFQ/N, mppOFQ/N160-176, or dynorphinA1-13. It also shows minimal cross-reactivity with mppOFQ/N181-187.Thus, the potential internal RRR cleavage site in pOFQ/N160-187must be intact for full reactivity (Mathis et al., 2001). Vacuum-driedsamples were resuspended in phosphate buffer containing $beta$ -mercaptoethanoland BSA for RIA. All of the RIA procedures were performed as describedpreviously (Quigley et al., 1998). The RIAs have a sensitivityof ~1.8 × 10³ pmol/tube. Recovery of input immunoreactivity of single or pooledbrain tissues was ~85-90%. All peptide nomenclature is based onthe mouse primary amino acid sequences of pOFQ/N andPOMC.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Lack of a functional PC2 decreases $beta$ -LPH conversion to $gamma$ -LPH and $beta$ -endorphin and abolishes carboxy-shortening of $beta$ -endorphin 1-31 in vivo

We fractionated WT and mutant hypothalamic extracts by RP-HPLC and assayed the fractions for $beta$ -endorphin and $beta$ -MSH immunoreactivity.In the WT hypothalamus, almost all of the $beta$ -MSH immunoreactivityis present as $gamma$ -LPH (Fig. 2A). However, in the PC2-deficient mice,only approximately one-third of the $beta$ -LPH was converted to $gamma$ -LPHand $beta$ -endorphin. This result suggests that PC2 is required tocomplete the in vivo conversion of $beta$ -LPH to $gamma$ -LPH and $beta$ -endorphin1-31. Figure 2B confirms that the major peak of immunoreactivematerial at 76 min is $beta$ -LPH, as demonstrated by a single, largepeak containing essentially equal amounts of $beta$ -endorphin and $beta$ -MSHimmunoreactivity. An additional peak of $beta$ -MSH immunoreactivityat 43 min in the WT animals is absent in the mutants. This peptideis a C-terminal fragment of $gamma$ -LPH derived from a cleavage at leu10-glu11of $gamma$ -LPH (Thorne and Thomas, 1990).

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Figure 2. $beta$ -LPH domain processing in WT and PC2 mutant mouse hypothalamic extracts. RP-HPLC fractions were assayed for $beta$ -endorphin and $beta$ -MSH immunoreactivity. The dashed line indicates the acetonitrile gradient. A, WT $beta$ -MSH and mutant animals. B, Mutant PC2. Results shown are representative of four separate determinations.

We subsequently determined the relative sizes of the $beta$ -endorphin-immunoreactive material by gel-exclusion chromatography ofWT and PC2-deficient hypothalamic extracts. Figure 3 shows thatessentially all of the $beta$ -LPH has been converted to $beta$ -endorphin-sizedmaterial in the WT hypothalamus, as was found in the RP-HPLC analyses,whereas in the PC2-deficient animals, only approximately one-thirdof the $beta$ -LPH was converted to $beta$ -endorphin. The inset in Figure3 shows that only ~34% of $beta$ -LPH was cleaved to $beta$ -endorphin, whereasin the WT animals, ~96% of the $beta$ -LPH was converted to $beta$ -endorphin-sizedmaterial.

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Figure 3. Sephadex G-50 gel-exclusion chromatography of WT and mutant PC2 hypothalamic extracts. The fractions were assayed for $beta$ -endorphin immunoreactivity. The arrow indicates the elution position of ¹²⁵I-acetyl- $beta$ -endorphin 1-27. V₀, Exclusion volume; V_t, total column volume. The inset shows the percentage of conversion of $beta$ -LPH to $beta$ -endorphin in a WT compared with a PC2 mutant mouse hypothalamus. The percentage of conversion is the ratio of the immunoreactivity eluting 3-3.5 kDa $beta$ -endorphin to the total $beta$ -endorphin immunoreactivity. Several RP-HPLC analyses were used for this calculation. n = 3; p = 0.0063; unpaired t test using StatView (Abacus Concepts, Calabasas, CA).

PC2 has been proposed to convert $beta$ -endorphin 1-31 to its carboxy-shortened form, $beta$ -endorphin 1-27 (Zhou and Mains, 1994).To determine whether mouse hypothalamic $beta$ -endorphin 1-31 is carboxy-shortened,we fractionated extracts by gel filtration as in Figure 3, pooledthe $beta$ -endorphin-sized material, and fractionated the pooled fractionsusing a gradient that was slightly different from that shown inFigure 2. Figure 4A shows that in the WT hypothalamus, some ofthe $beta$ -endorphin 1-31 (~40%) has been converted to $beta$ -endorphin1-27 and 1-26. Figure 4B shows that the $beta$ -endorphin 1-31 was notprocessed to carboxy-shortened peptides to any appreciable extentin the mutant hypothalamus. The small amount of immunoreactivematerial eluting at 62-64 min is $beta$ -LPH carryover from the pooledfractions.

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Figure 4. RP-HPLC fractionation of WT and PC2-deficient mouse hypothalamic extracts after gel exclusion, as in Figure 3. The pooled extracts of $beta$ -endorphin-sized material were fractionated on the gradient indicated, and the fractions were assayed for $beta$ -endorphin immunoreactivity. The arrows indicate the elution times of authentic $beta$ -endorphin peptides. The dashed line indicates the acetonitrile gradient. Similar results were seen in two experiments. Ac, Acetyl.

Lack of a functional PC2 causes incomplete conversion of pOFQ/N to OFQ/N in vivo

We then examined the extent of ppOFQ/N processing in PC2-deficient mice using an antibody to OFQ (1-17) that can recognizebiosynthetic intermediates (BSIs), as well as the proprotein.Figure 5A shows that in the WT hypothalamus virtually all of theOFQ/N immunoreactivity elutes at 31 min. In contrast, Figure 5Bshows that although some OFQ/N is produced and elutes at 30-31min, relatively large amounts of a pOFQ/N-like molecule eluteat 70 min. Potential BSIs containing the OFQ/N epitope (66-67min) were also detected in hypothalamic extracts obtained fromPC2 mutant mice. Figure 5C shows that proteolytic processing inthe heterozygote is very similar to the processing observed inthe WT, indicating that one-half of the PC2 enzymatic activityexpressed in the heterozygotes is sufficient to produce WT proteolytic-processingpatterns. We also noted a reduction in the total amount of OFQ/N-immunoreactivematerial contained in extracts from PC2 mutant animals. Theseresults indicate that PC2 is required for complete processingof the OFQ/N precursor and OFQ/N-containing intermediates; itsabsence causes a substantial reduction in OFQ/N immunoreactivity.

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Figure 5. RP-HPLC fractionation of (WT) and PC2 mutant mouse hypothalamic extracts (one mouse hypothalamic equivalent). Extracts from WT (A), PC2-deficient (B), and heterozygous (C) mice were fractionated using a linear gradient of 8-36% acetonitrile (dashed line). The fractions were assayed for OFQ/N immunoreactivity. The arrow indicates the elution position of synthetic OFQ/N. The profile shown is representative of four separate determinations.

To more fully characterize the effects on OFQ/N processing, we fractionated hypothalamic extracts by gel-exclusion chromatography.The open circles in Figure 6 indicate that virtually all of theOFQ/N immunoreactivity co-elutes with ¹²⁵I-OFQ/N in WT animals, whereas larger relative amounts of pOFQ/N-sizedmaterial were detected in the PC2 mutant animals. As with theHPLC fractionations, much smaller amounts of OFQ/N immunoreactivityrelative to the proprotein were detected in the PC2-defectiveanimals. The inset in Figure 6 shows that using the HPLC fractionations,only ~30% of the total immunoreactivity is converted to OFQ/Nin the mutants, compared with ~98% in the WT animals. The totalamount of OFQ/N immunoreactivity found in the HPLC fractionationsfrom mutant mice ranged from 10 to 40% of WT values.

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Figure 6. Sephadex G-50 chromatography of WT and PC2 mutant mouse hypothalamic extracts. Gel filtration was performed as described in Materials and Methods. Portions of the fractions were vacuum dried and assayed for OFQ/N immunoreactivity. ¹²⁵I-OFQ/N elutes at fraction 55. Cytochrome C (molecular mass, 22.5 kDa) elutes at fraction 33-34. V₀, Exclusion volume; V_t, total column volume. Conversion of total OFQ/N immunoreactivity to mature peptide in WT and PC2 mutant mouse hypothalamus is shown in the inset. The percentage of conversion is the ratio of the immunoreactivity co-eluting with synthetic OFQ/N at 31 min to the total OFQ/N immunoreactivity. We used RP-HPLC analyses for this calculation. n = 3; p = 0.002; unpaired t test using StatView.

We also examined proteolytic processing of OFQ/N in the amygdala. In the WT amygdala, virtually all of the immunoreactiveOFQ/N eluted at 31-32 min (Fig. 7), similar to our previous findingsanalyzing hypothalamic extracts. In the PC2-deficient mice, thepeak of OFQ/nociceptin was greatly reduced, and new peaks of immunoreactivitywere detected at 71 min (pOFQ/N) and 66-67 min (Fig. 7, filledcircles). Thus, in both the amygdala and the hypothalamus of thePC2 mutants, small amounts of OFQ/N were produced; however, processingdoes not proceed to completion, because unprocessed and partiallyprocessed immunoreactive material containing the OFQ/N epitopewere detected. We also found that in the amygdala, as in the hypothalamus,the level of mature OFQ/N immunoreactivity was dramatically reducedin the mutants. This result again supports the notion that PC2is required for complete conversion of pOFQ/N to the 17 aminoacid OFQ/N peptide in the brain.

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Figure 7. RP-HPLC fractionation of WT and PC2 mutant amygdala extracts. Extracts from WT animals (open circles) and PC2 mutant animals (filled circles) were fractionated using a linear gradient of 8-36% acetonitrile (dashed line). The fractions were assayed for OFQ/N immunoreactivity. The arrow indicates the elution time of synthetic OFQ/N. The profile shown is representative of four separate determinations.

In addition, we assayed the HPLC fractions using an RIA directed against the C terminus of the OFQ/N proprotein (Mathis etal., 2001). In the WT and heterozygote hypothalamus, we foundtwo major peaks of C-terminus immunoreactivity eluting at 62 and66 min, with synthetic C-terminal peptide eluting at 62 min (Fig.8A). As shown previously, OFQ/N elutes at 31 min (Fig. 5A). Inthe mutant animals, the major peak of both OFQ/N and C-terminalimmunoreactivity eluted at 71 min, and the relative amounts ofimmunoreactivity eluting at 62 and 66 min decreased markedly (Fig.8B). These results support the notion that a moiety eluting at71 min contains both the C-terminal and OFQ/N epitope and is mostlikely pOFQ/N. The peaks eluting at 62 and 66 min appear to bethe full-length C-terminal peptide and a derivative containingan intact internal RRR sequence.

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Figure 8. Fractionation of pOFQ/N C-terminal (c-term)-containing peptides in WT and PC-2-deficient mice. Extracts were fractionated as described in Figure 5, and the fractions were assayed for OFQ/N and C-terminal peptide immunoreactivity. The elution positions of synthetic peptides are indicated by the arrows. The dashed line indicates the percentage of acetonitrile. A, Heterozygote; B, PC null.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The proteolytic processing patterns of POMC-derived peptides have been studied previously in the rat hypothalamus (Emesonand Eipper, 1986). Those studies demonstrated that POMC processingin the hypothalamus resembled the processing pattern in the neurointermediatepituitary rather than the anterior pituitary (Eipper and Mains,1981; Emeson and Eipper, 1986). The exception to this was thelack of acetylation needed to produce $alpha$ -N-acetylated endorphinsand MSH. Thus, in the rat, almost all of the hypothalamic $beta$ -LPHwas converted to $beta$ -endorphin 1-31-related molecules, and approximatelyone-third of this population was carboxy-shortened. We found essentiallythe same result in the WT mouse hypothalamus (Figs. 3, 4).

Zhou and Mains (1994) found that overexpression of PC2 in AtT-20 anterior pituitary cells resulted in enhanced proteolyticcleavages at specific, paired-basic sites. In the case of PC2,it enhanced the conversion of $beta$ -LPH to $gamma$ -LPH and $beta$ -endorphin andproduced carboxy-shortened $beta$ -endorphin 1-27. As predicted, wefound no carboxy-shortened $beta$ -endorphins in the hypothalamus ofmice lacking a functional PC2; thus, PC1 does not cleave at the $beta$ -endorphin C-terminal KK site in vivo. We found that lack ofa functional PC2 greatly diminished (by two-thirds) the conversionof $beta$ -LPH to $gamma$ -LPH and $beta$ -endorphin in vivo. We did not find anyincrease in unprocessed POMC in brain tissues from the mutantmice, unlike our studies of pituitary POMC processing in PC2 mutantmice (Allen et al., 1999).

The results obtained by examining pOFQ/N processing in specific brain tissues were in contrast to these observations. In boththe hypothalamus and the amygdala, we found that lack of a functionalPC2 resulted in an increase in unprocessed OFQ/N-containing material,including pOFQ/N. Also, in contrast to the POMC pathway, therewas a reduction in the OFQ/N immunoreactivity in both the hypothalamusand amygdala of the mutant animals. The decrease in the productionof mature OFQ/N suggests that PC2 is much more active than PC1in cleaving the KR sites bounding OFQ/N (Fig. 1B). The PC2-deficientmice used here have been examined for DYN processing in the brain(Berman et al., 2000). These studies showed a substantial reductionin DYN A8, DYN A17, and DYN B13, and it was concluded that PC2was critical for DYN peptideproduction.

The presence of PC2 activity completes the conversion of $beta$ -LPH to $beta$ -endorphin and carboxy-shortens some of the $beta$ -endorphin1-31 to $beta$ -endorphin 1-27 in vitro. PC2 is autoactivated in theacidic environment of a late post-Golgi compartment (Lamango etal., 1999), and it is after early cleavages by PC1 that PC2 performsits functions. Our studies confirm the in vitro studies usingPOMC pituitary cells as a model; however, in vivo, PC1 (presumably)was able to convert a substantial amount of $beta$ -LPH to $gamma$ -LPH and $beta$ -endorphin, as seen in the mutant animals (Fig. 2A). In fact,the processing profile resembles the pattern found in the mouseanterior pituitary (Eipper and Mains, 1980). This general scenarioholds true with regard to some of the pOFQ/N cleavages at KR sites(Fig. 1), but unlike the $beta$ -endorphin immunoreactivity, we founda reduction in OFQ/N immunoreactivity in the mutant, as well asrelative increases in unprocessed prohormone and a putative biosyntheticintermediate. Thus, the effects of a nonfunctional PC2 on propeptideprocessing are different, depending on which proprotein pathwayis examined. What still remains unclear is what prevents PC1 fromcompletely cleaving at all of the KR sites examined in our studies.There is no sequence homology bounding the KR sites examined herein either pOFQ/N or POMC; thus, site-specific amino acid sequencehomology does not explain why conversionstops.

Very recently an inhibitor of PC1 called proSAAS has been cloned and characterized (Fricker et al., 2000). The expressionof proSAAS in AtT-20 cells results in a substantial reductionin the rate of endogenous POMC processing. We know that thereare activators of PCs, because the 7B2 protein is essential forthe activation and maturation of PC2 (Lamango et al., 1999). Becausethere are specific inhibitors and activators for PCs, their existencemay provide the answer to the incomplete conversion at specificKR sites in POMC and pOFQ/N. PC1 and PC2 show temporal and spatialexpression during development (Marcinkiewicz et al., 1993; Zhenget al., 1994); thus, it will also be interesting to examine theeffects of PC2 deficiency on pOFQ/N and POMC processing duringfetaldevelopment.

We have shown that the lack of functional PC2 produces aberrant processing in two neuroendocrine prohormone pathways. Notonly is PC2 required for site-specific cleavages, but it alsoappears to play a role in the conversion of certain intermediatesin vivo. In the case of pOFQ/N, PC2 appears to affect the amountof end product peptide produced. We have also shown that expressionof a nonfunctional PC2 can affect processing in a prohormone-specificmanner. The ability to generate multiple biological activitiesfrom a given prohormone is an efficient way to create physiologicaldiversity without the use of gene products encoding each peptideseparately. It has been shown previously that PC1 and PC2 canbe regulated by a variety of modulators, such as neurotransmitters,steroid hormones, and hypothalamic releasing factors (Day et al.,1992). The combination of such regulation and potentially selectiveexpression of inhibitors and activators for the PCs creates anew level of complexity in producing bioactivities fromprohormones.

  FOOTNOTES

Received Jan. 10, 2001; revised May 9, 2001; accepted May 22, 2001.

This work was supported in part by National Institutes of Health Grants DA11282 (R.G.A.), DA08562 and DA10703 (D.K.G.), andDA08622 (J.E.P.). We thank D. F. Steiner and the University ofChicago Diabetes Research and Training Center for providing thePC2 null mouse strain. We also thank Dan Austin and HarleneFinn.
Correspondence should be addressed to Dr. Richard G. Allen, Oregon Health Sciences University, The Center for Research onOccupational and Environmental Toxicology, 3181 Southwest SamJackson Park Road, L606, Portland, OR 97201. E-mail: allenr{at}ohsu.edu.

  REFERENCES

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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