The v-sis protein retains biological activity as a type II membrane protein when anchored by various signal-anchor domains, including the hydrophobic domain of the bovine papilloma virus E5 oncoprotein

Membrane-anchored forms of the v-sis oncoprotein have been previously described which are oriented as type I transmembrane proteins and which efficiently induce autocrine transformation. Several examples of naturally occurring membrane-anchored growth factors have been identified, but all exhibit a type I orientation. In this work, we wished to construct and characterize membrane-anchored growth factors with a type II orientation. These experiments were designed to determine whether type II membrane-anchored growth factors would in fact exhibit biological activity. Additionally, we wished to determine whether the hydrophobic domain of the E5 oncoprotein of bovine papilloma virus (BPV) can function as a signal-anchor domain to direct type II membrane insertion. Type II derivatives of the v-sis oncoprotein were constructed, with the NH2 terminus intracellular and the COOH terminus extracellular, by substituting the NH2 terminal signal sequence with the signal-anchor domain of a known type II membrane protein. The signal-anchor domains of neuraminidase (NA), asialoglycoprotein receptor (ASGPR) and transferrin receptor (TR) all yielded biologically active type II derivatives of the v-sis oncoprotein. Although transforming all of the type II signal/anchor-sis proteins exhibited a very short half-life. The short half-life exhibited by the signal/anchor-sis constructs suggests that, in some cases, cellular transformation may result from the synthesis of growth factors so labile that they activate undetectable autocrine loops. The E5 oncoprotein encoded by BPV exhibits amino acid sequence similarity with PDGF, activates the PDGF beta-receptor, and thus resembles a miniature membrane-anchored growth factor with a putative type II orientation. The hydrophobic domain of the E5 oncoprotein, when substituted in place of the signal sequence of v-sis, was indistinguishable compared with the signal-anchor domains of NA, TR, and ASGPR, demonstrating its ability to function as a signal-anchor domain. NIH 3T3 cells transformed by the signal/anchor-sis constructs exhibited morphological reversion upon treatment with suramin, indicating a requirement for ligand/receptor interactions in a suramin- sensitive compartment, most likely the cell surface. In contrast, NIH 3T3 cells transformed by the E5 oncoprotein did not exhibit morphological reversion in response to suramin.     

Requirements for the membrane insertion of signal-anchor type proteins

Proteins which are inserted and anchored in the membrane of the ER by an uncleaved signal-anchor sequence can assume two final orientations. Type I signal-anchor proteins translocate the NH2 terminus across the membrane while type II signal-anchor proteins translocate the COOH terminus. We investigated the requirements for cytosolic protein components and nucleotides for the membrane targeting and insertion of single-spanning type I signal-anchor proteins. Besides the ribosome, signal recognition particle (SRP), GTP, and rough microsomes (RMs) no other components were found to be required. The GTP analogue GMPPNP could substitute for GTP in supporting the membrane insertion of IMC-CAT. By using a photocrosslinking assay we show that for secreted, type I and type II signal-anchor proteins the presence of both GTP and RMs is required for the release of the nascent chain from the 54-kD subunit of SRP. For two of the proteins studied the release of the nascent chain from SRP54 was accompanied by a new interaction with components of the ER. We conclude that the GTP-dependent release of the nascent chain from SRP54 occurs in an identical manner for each of the proteins studied.     

Functional expression of bovine 17 alpha-hydroxylase in COS 1 cells is dependent upon the presence of an amino-terminal signal anchor sequence.

Microsomal forms of eukaryotic cytochrome P450 proteins are integral membrane proteins of the endoplasmic reticulum (ER) membrane which are targeted to the ER via the signal recognition particle pathway. A hydrophobic amino terminus serves as a combined signal sequence and major membrane anchor (signal-anchor sequence) for the microsomal P450s. We have examined the insertion of bovine 17 alpha-hydroxylase (P45017 alpha) into the ER of COS 1 cells in order to evaluate the role of membrane insertion of the amino-terminal signal-anchor of microsomal P450s as a functional determinant for these enzymes. Previously, we have shown that deletion of the hydrophobic amino terminus from P45017 alpha reduced membrane targeting and insertion by 5-fold compared with the wild-type protein, abolished enzymatic activity, and resulted in an aberrant CO difference spectrum. In the present study we have replaced the amino terminus of P45017 alpha with two heterologous signal-anchor sequences, one that is similar and one that is very different from the P45017 alpha sequence. The chimeric proteins were expressed in COS 1 cells. Immunoblot analysis of isolated microsomal membranes show that the heterologous signal-anchor sequences functioned to target the P45017 alpha protein to the ER. Enzymatic assays in intact COS 1 cells indicate that both the chimeric proteins are efficient 17 alpha-hydroxylase enzymes. The amino terminus of P45017 alpha was also replaced with a sequence that is not a signal-anchor, and the expressed protein was neither targeted to the ER nor was functional in COS 1 cells. In conclusion, both the structure and catalytic activity of P45017 alpha in COS 1 cells is dependent upon an amino-terminal sequence that functions as a signal-anchor sequence and not upon the precise sequence of the amino terminus.     

The identification of proteins in the proximity of signal-anchor sequences during their targeting to and insertion into the membrane of the ER

Using a photocross-linking approach we have investigated the cytosolic and membrane components involved in the targeting and insertion of signal-anchor proteins into the membrane of the ER. The nascent chains of both type I and type II signal-anchor proteins can be cross-linked to the 54-kD subunit of the signal recognition particle. Upon addition of rough microsomes the type I and type II signal-anchor proteins interact with a number of components. Both types of protein interact with an integral membrane protein, the signal sequence receptor, previously identified by its proximity to preprolactin during its translocation (Wiedmann, M., T.V. Kurzchalia, E. Hartmann, and T.A. Rapoport. 1987. Nature [Lond.] 328:830-833). Three proteins, previously unidentified, were found to be cross-linked to the nascent chains of the signal-anchor proteins. Among them was a 37-kD protein that was found to be the main component interacting with the type I SA protein used. These proteins were not seen in the absence of membranes suggesting they are components of the ER. The ability of the nascent chains to be cross-linked to these identified proteins was shown to be abolished by prior treatment with agents known to disrupt translocation intermediates or ribosomes. We propose that the newly identified proteins function either in the membrane insertion of only a subset of proteins or only at a specific stage of insertion.     

A tripartite structure of the signals that determine protein insertion into the endoplasmic reticulum membrane

Multilineage colony stimulating factor is a secretory protein with a cleavable signal sequence that is unusually long and hydrophobic. Using molecular cloning techniques we exchanged sequences NH2- or COOH-terminally flanking the hydrophobic signal sequence. Such modified fusion proteins still inserted into the membrane but their signal sequence was not cleaved. Instead the proteins were now anchored in the membrane by the formerly cleaved signal sequence (signal-anchor sequence). They exposed the NH2 terminus on the exoplasmic and the COOH terminus on the cytoplasmic side of the membrane. We conclude from our results that hydrophilic sequences flanking the hydrophobic core of a signal sequence can determine cleavage by signal peptidase and insertion into the membrane. It appears that negatively charged amino acid residues close to the NH2 terminal side of the hydrophobic segment are compatible with translocation of this segment across the membrane. A tripartite structure is proposed for signal-anchor sequences: a hydrophobic core region that mediates targeting to and insertion into the ER membrane and flanking hydrophilic segments that determine the orientation of the protein in the membrane.     

A part of the transmembrane domain of pro-TNF can function as a cleavable signal sequence that generates a biologically active secretory form of TNF.

To determine the minimum requirement in the 76-residue leader sequence of pro-tumor necrosis factor (TNF) for membrane translocation across the endoplasmic reticulum (ER) and for the maturation of pro-TNF, we constructed pro-TNF mutants in which a part of the transmembrane domain of pro-TNF was directly linked to the N-terminus of the mature domain, and evaluated their translocational behavior across the ER-membrane and their secretion from the transfected cells. The in vitro translation/translocation assay involving a canine pancreatic microsomal membrane system including a mutant, Delta-75-47, -32-1, revealed that the N-terminal half of the transmembrane domain of pro-TNF consisting of 14 residues functioned as a cleavable signal sequence; it generated a cleaved form of TNF having a molecular mass similar to that of mature TNF. Analysis of the cleavage site by site-directed mutagenesis indicated that the site was inside the leader sequence of this mutant. When the mutant, Delta-75-47, -32-1, was expressed in COS-1 cells, efficient secretion of a biologically active soluble TNF was observed. Further deletion of the hydrophobic domain from this mutant inhibited the translocation, indicating that some extent of hydrophobicity is indispensable for the membrane translocation of the mature domain of TNF. Thus, the N-terminal half of the transmembrane domain of pro-TNF could function as a cleavable signal sequence when linked to the mature domain of TNF, and secretion of a biologically active secretory form of TNF could be achieved with this 14-residue hydrophobic segment. In intact pro-TNF, however, this 14-residue sequence could not function as a cleavable signal sequence during intracellular processing, indicating that the remainder of the 76-residue leader sequence of pro-TNF inhibits the signal peptide cleavage and thus enables the leader sequence to function as a type II signal-anchor sequence that generates a transmembrane form of TNF.     

Signal and membrane anchor functions overlap in the type II membrane protein I gamma CAT

I gamma CAT is a hybrid protein that inserts into the membrane of the endoplasmic reticulum as a type II membrane protein. These proteins span the membrane once and expose the NH2-terminal end on the cytoplasmic side and the COOH terminus on the exoplasmic side. I gamma CAT has a single hydrophobic segment of 30 amino acid residues that functions as a signal for membrane insertion and anchoring. The signal-anchor region in I gamma CAT was analyzed by deletion mutagenesis from its COOH-terminal end (delta C mutants). The results show that the 13 amino acid residues on the amino-terminal side of the hydrophobic segment are not sufficient for membrane insertion and translocation. Mutant proteins with at least 16 of the hydrophobic residues are inserted into the membrane, glycosylated, and partially proteolytically processed by a microsomal protease (signal peptidase). The degree of processing varies between different delta C mutants. Mutant proteins retaining 20 or more of the hydrophobic amino acid residues can span the membrane like the parent I gamma CAT protein and are not proteolytically processed. Our data suggest that in the type II membrane protein I gamma CAT, the signals for membrane insertion and anchoring are overlapping and that hydrophilic amino acid residues at the COOH-terminal end of the hydrophobic segment can influence cleavage by signal peptidase. From this and previous work, we conclude that the function of the signal-anchor sequence in I gamma CAT is determined by three segments: a positively charged NH2 terminus, a hydrophobic core of at least 16 amino acid residues, and the COOH-terminal flanking hydrophilic segment.     

Intramembrane proteolysis and endoplasmic reticulum retention of hepatitis C virus core protein

Hepatitis C virus (HCV) core protein is suggested to localize to the endoplasmic reticulum (ER) through a C-terminal hydrophobic region that acts as a membrane anchor for core protein and as a signal sequence for E1 protein. The signal sequence of core protein is further processed by signal peptide peptidase (SPP). We examined the regions of core protein responsible for ER retention and processing by SPP. Analysis of the intracellular localization of deletion mutants of HCV core protein revealed that not only the C-terminal signal-anchor sequence but also an upstream hydrophobic region from amino acid 128 to 151 is required for ER retention of core protein. Precise mutation analyses indicated that replacement of Leu(139), Val(140), and Leu(144) of core protein by Ala inhibited processing by SPP, but cleavage at the core-E1 junction by signal peptidase was maintained. Additionally, the processed E1 protein was translocated into the ER and glycosylated with high-mannose oligosaccharides. Core protein derived from the mutants was translocated into the nucleus in spite of the presence of the unprocessed C-terminal signal-anchor sequence. Although the direct association of core protein with a wild-type SPP was not observed, expression of a loss-of-function SPP mutant inhibited cleavage of the signal sequence by SPP and coimmunoprecipitation with unprocessed core protein. These results indicate that Leu(139), Val(140), and Leu(144) in core protein play crucial roles in the ER retention and SPP cleavage of HCV core protein.     

Insertion of a multispanning membrane protein occurs sequentially and requires only one signal sequence

To study the insertion of multispanning membrane proteins into the endoplasmic reticulum, we constructed novel proteins on the cDNA level by repeating, up to four times, the internal signal-anchor domain of the asialoglycoprotein receptor H1. Upon in vitro translation in the presence of microsomes, these polypeptides are indeed inserted as polytopic membrane proteins. The first hydrophobic domain functions as a signal and the second as a stop-transfer sequence, while the third initiates a second translocation process, halted again by the fourth. We were able to demonstrate that insertion occurs sequentially, starting with the first apolar segment from the amino terminus. By replacing the original signal-anchor domains by a mutant sequence not recognized by signal recognition particle (SRP), it was shown that only the first hydrophobic domain needs to be a signal sequence and that the second translocation event does not require SRP.     

Membrane insertion of gap junction connexins: polytopic channel forming membrane proteins

Connexins, the proteins that form gap junction channels, are polytopic plasma membrane (PM) proteins that traverse the plasma membrane bilayer four times. The insertion of five different connexins into the membrane of the ER was studied by synthesizing connexins in translation- competent cell lysates supplemented with pancreatic ER-derived microsomes, and by expressing connexins in vivo in several eucaryotic cell types. In addition, the subcellular distribution of the connexins was determined. In vitro-synthesis in the presence of microsomes resulted in the signal recognition particle-dependent membrane insertion of the connexins. The membrane insertion of all connexins was accompanied by an efficient proteolytic processing that was dependent on the microsome concentration. Endogenous unprocessed connexins were detectable in the microsomes used, indicating that the pancreatic microsomes serve as a competent recipient in vivo for unprocessed full length connexins. Although oriented with their amino terminus in the cytoplasm, the analysis of the cleavage reaction indicated that an unprecedented processing by signal peptidase resulted in the removal of an amino-terminal portion of the connexins. Variable amounts of similar connexin cleavage products were also identified in the ER membranes of connexin overexpressing cells. The amount generated correlated with the level of protein expression. These results demonstrate that the connexins contain a cryptic signal peptidase cleavage site that can be processed by this enzyme in vitro and in vivo in association with their membrane insertion. Consequently, a specific factor or condition must be required to prevent this aberrant processing of connexins under normal conditions in the cell.     

Functional limits of conformation, hydrophobicity, and steric constraints in prokaryotic signal peptide cleavage regions. Wild type transport by a simple polymeric signal sequence

These experiments examine the role of conformation, hydrophobicity, and steric constraints in the function of the prokaryotic signal peptide cleavage region. The experimental strategy involves replacement of the wild type Escherichia coli alkaline phosphatase signal peptide cleavage region with a series of idealized model sequences designed to epitomize the particular structural and physical variables under study. By analyzing model sequences whose conformations have been determined by physical studies, we have demonstrated that efficient transport does not depend on the structural preference of the cleavage region. Although previous studies based on Chou-Fasman analysis have suggested that the cleavage region forms a beta-turn which is required for transport, our results demonstrate that either a beta-turn- or alpha-helix-fostering sequence in the cleavage region functions indistinguishably from wild type. Furthermore, the presence of a proline residue between the core and cleavage region, although common in natural sequences, is not essential for export. Cleavage regions of varying hydrophobicities can support translocation across the inner membrane, but the placement of bulky residues at positions -1 and -3 upstream of the cleavage site abolishes processing and transport to the periplasm. By reducing the signal peptide to simplified, idealized segments, this study has identified a largely polymeric sequence, MKQST(L10)-(A6), that functions equivalently to the wild type alkaline phosphatase signal peptide. This work starts to provide a basis for the design of a universal prokaryotic signal peptide that incorporates all the critical physical and structural characteristics required for transport function.     

A eukaryotic carboxyl-terminal signal sequence translocating large hydrophilic domains across membranes

Yeast Golgi ecto-ATPase Ynd1p is an unusual type III membrane protein with the longest translocated N-terminus reported. Sequential deletion analysis reveals that translocation of this 500-residue-long hydrophilic domain across the membranes requires the C-terminal transmembrane domain of Ynd1p and its flanking regions. Additional studies indicate that the topogenic sequence of Ynd1p overrides the effect of a reverse signal-anchor sequence present at the N-terminus of Ynd1p, while it is not affected by a classic signal sequence at the N-terminus. When placed at the C-terminal end, the sequence can translocate large extracellular domains of two membrane proteins across the membranes. The data demonstrate the existence of a true eukaryotic C-terminal signal sequence.     

Membrane orientation of carboxyl-terminal half P-glycoprotein: topogenesis of transmembrane segments.

Multiple topological orientations of the carboxyl-terminal half of P-glycoprotein have been observed. One orientation is consistent with the hydropathy-predicted model and contains six transmembrane (TM)-spanning regions. In another orientation, the cytoplasmic-predicted loop between TM8 and TM9 is extracellular and glycosylated. In support of this "alternative" topology, TM8 was previously established to function as a signal-anchor sequence to insert with its amino-terminal end in the cytoplasm and the carboxyl-terminal end in the extracytoplasmic space. However, it is unclear how downstream TM segments fold in the membrane when TM8 functions as a signal-anchor sequence. Here, we created several chimeric Pgp molecules to examine the membrane insertion of TM segments 9 and 10 using a cell-free system. We found that TM9 functions as a stop-transfer sequence when following the signal-anchor sequence, TM8. However, the stop-transfer activity of TM9 depends on the presence of TM10. In the absence of TM10, TM9 partially translocated across the membrane into the endoplasmic reticulum lumen. In contrast, TM9 efficiently stopped the translocation event of the nascent chain in the presence of TM10. Our results suggest that the membrane insertion of TM8 and TM9 establishes the extracellular loop between TM8 and TM9. Formation of this loop apparently involves the interactions between Pgp TM segments, which facilitate proper folding of the Pgp carboxyl-terminal half.     

Manipulation of membrane protein topology on the endoplasmic reticulum by a specific ligand in living cells

Almost all integral membrane proteins in the secretory pathway are cotranslationally inserted into the endoplasmic reticulum membrane. Their membrane topology is determined by their amino acid sequences. Here we show that the topology can be manipulated by a factor other than the amino acid sequence. A dihydrofolate reductase (DHFR) domain was fused to the N-terminus of the type I signal-anchor sequence of synaptotagmin II, which mediates translocation of the preceding portion. The DHFR domain was translocated through the membrane in COS7 cells and a transmembrane (TM) topology was achieved. When a DHFR ligand, methotrexate, was added to the culture medium, translocation of the DHFR domain was suppressed and both ends of the signal-anchor sequence remained on the cytoplasmic side. In contrast, translocation of the DHFR domain fused after the signal peptide, which translocates the following region, was not affected by the ligand. The topology-altered fusion protein was anchored to the membrane in a high salt-resistant state, and partially extracted from the membrane under alkali conditions. We concluded that the topology of membrane proteins can be manipulated by a trans-acting factor, even in living cells.     

Sec61p contributes to signal sequence orientation according to the positive-inside rule

Protein targeting to the endoplasmic reticulum is mediated by signal or signal-anchor sequences. They also play an important role in protein topogenesis, because their orientation in the translocon determines whether their N- or C-terminal sequence is translocated. Signal orientation is primarily determined by charged residues flanking the hydrophobic core, whereby the more positive end is predominantly positioned to the cytoplasmic side of the membrane, a phenomenon known as the "positive-inside rule." We tested the role of conserved charged residues of Sec61p, the major component of the translocon in Saccharomyces cerevisiae, in orienting signals according to their flanking charges by site-directed mutagenesis by using diagnostic model proteins. Mutation of R67, R74, or E382 in Sec61p reduced C-terminal translocation of a signal-anchor protein with a positive N-terminal flanking sequence and increased it for signal-anchor proteins with positive C-terminal sequences. These mutations produced a stronger effect on substrates with greater charge difference across the hydrophobic core of the signal. For some of the substrates, a charge mutation in Sec61p had a similar effect as one in the substrate polypeptides. Although these three residues do not account for the entire charge effect in signal orientation, the results show that Sec61p contributes to the positive-inside rule.     

A putative signal peptidase recognition site and sequence in eukaryotic and prokaryotic signal peptides

Presecretory signal peptides of 39 proteins from diverse prokaryotic and eukaryotic sources have been compared. Although varying in length and amino acid composition, the labile peptides share a hydrophobic core of approximately 12 amino acids. A positively charged residue (Lys or Arg) usually precedes the hydrophobic core. Core termination is defined by the occurrence of a charged residue, a sequence of residues which may induce a beta-turn in a polypeptide, or an interruption in potential alpha-helix or beta-extended strand structure. The hydrophobic cores contain, by weight average, 37% Leu: 15% Ala: 10% Val: 10% Phe: 7% Ile plus 21% other hydrophobic amino acids arranged in a non-random sequence. Following the hydrophobic cores (aligned by their last residue) a highly non-random and localized distribution of Ala is apparent within the initial eight positions following the core: (formula; see text) Coincident with this observation, Ala-X-Ala is the most frequent sequence preceding signal peptidase cleavage. We propose the existence of a signal peptidase recognition sequence A-X-B with the preferred cleavage site located after the sixth amino acid following the core sequence. Twenty-two of the above 27 underlined Ala residues would participate as A or B in peptidase cleavage. Position A includes the larger aliphatic amino acids, Leu, Val and Ile, as well as the residues already found at B (principally Ala, Gly and Ser). Since a preferred cleavage site can be discerned from carboxyl and not amino terminal alignment of the hydrophobic cores it is proposed that the carboxyl ends are oriented inward toward the lumen of the endoplasmic reticulum where cleavage is thought to occur. This orientation coupled with the predicted beta-turn typically found between the core and the cleavage site implies reverse hairpin insertion of the signal sequence. The structural features which we describe should help identify signal peptides and cleavage sites in presumptive amino acid sequences derived from DNA sequences.     

Signal peptidase can cleave inside a polytopic membrane protein

The signal peptides of most proteins targeted to the endoplasmic reticulum are specifically cleaved by signal peptidase. Although potential cleavage sites occur frequently in polytopic proteins after membrane-spanning segments, processing is restricted to the first hydrophobic domain, suggesting that signal peptidase might not have access to subsequently translocated, internal domains. To test this hypothesis, we replaced the third transmembrane segment of an artificial threefold membrane-spanning protein by a sequence which is normally an amino-terminal signal. Upon in vitro translation and insertion into microsomes, efficient cleavage at this sequence was observed, thus demonstrating the ability of signal peptidase to cleave within polytopic membrane proteins.     

An alternate pathway for the processing of the prolipoprotein signal peptide in Escherichia coli

Previous studies showed that when the signal sequence plus 9 amino acid residues from the amino terminus of the major lipoprotein of Escherichia coli was fused to beta-lactamase, the resulting hybrid protein was modified, proteolytically processed, and assembled into the outer membrane as was the wild-type lipoprotein (Ghrayeb, J., and Inouye, M. (1983) J. Biol. Chem. 259, 463-467). We have constructed several hybrid proteins with mutations at the cleavage site of the prolipoprotein signal peptide. These mutations are known to block the lipid modification of the lipoprotein at the cysteine residue, resulting in the accumulation of unprocessed, unmodified prolipoprotein in the outer membrane. The mutations blocked the lipid modification of the hybrid protein. However, in contrast to the mutant lipoproteins, the cleavage of the signal peptides for the mutant hybrid proteins did occur, although less efficiently than the unaltered prolipo-beta-lactamase. The mutant prolipo-beta-lactamase proteins were cleaved at a site 5 amino acid residues downstream of the prolipoprotein signal peptide cleavage site. This new cleavage between alanine and lysine residues was resistant to globomycin, a specific inhibitor for signal peptidase II. This indicates that signal peptidase II, the signal peptidase which cleaves the unaltered prolipo-beta-lactamase, is not responsible for the new cleavage. The results demonstrate that the cleavage of the signal peptide is a flexible process that can occur by an alternative pathway when the normal processing pathway is blocked.     

Mutagenesis of Rat Dopamine β-Hydroxylase: Examination in Cell-Free System

Abstract: Dopamine β-hydroxylase (DBH; EC 1.14.17.1) exists as membrane-bound and soluble forms in neurosecretory vesicles. The features of DBH required for glycosylation and incorporation into membranes were studied in a cell-free system. Translation of full-length DBH with microsomal membranes generated two glycosylated products (GH and GL) depending on the magnesium concentration. Carboxyl-terminal, in contrast to amino-terminal, truncations gave translation products that were glycosylated by microsomal membranes. Site-directed mutants were generated with the second AUG codon and the region of a putative signal sequence cleavage site modified. Translation without membranes indicated that the second AUG is not used to initiate translation. The mutant with Glu⁴¹→ Leu⁴¹ and Ser⁴³→ Thr⁴³ yielded only the GH form with membranes, whereas mutation of Ser⁴³→ Ala⁴³ generated both GH and GL forms. Both glycosylated forms comigrated with the microsomal membranes on sucrose gradients. Endoglycosidase H digestion indicated that the differences between the GH and GL forms are not due to the sugar moiety. The results suggest a role for cleavage of a signal sequence in the formation of different forms of DBH. The possibility that these mutations change the secondary structure near the signal cleavage site, affecting processing, is discussed.