(Received for publication, March 18, 1997, and in revised form, April 9, 1997)
From the J. Holland Laboratory, American Red Cross, Rockville, Maryland 20855
We have previously described the expression of the human proprotein convertase furin or paired basic amino acid-cleaving enzyme, in mice transgenic for paired basic amino acid-cleaving enzyme and human Protein C (HPC). Here we show 100-fold or higher expression of furin in the mammary gland, compared with endogenous furin. Furin and recombinant HPC were detected in the same regions of the mammary gland and regulated similar to the endogenous whey acidic protein. In addition to the expected intracellular localization, furin was secreted into the milk as an 80-kDa form lacking the transmembrane and cytoplasmic domains. Furin present at levels of up to 40,000 units/ml milk cleaved the t-butoxycarbonyl-RVRR-AMC substrate with a Km of 32 µM, and processed the recombinant HPC precursor at the appropriate sites. Surprisingly, the expression of an active protease was not toxic to the mammary gland. This is a rare example of an animal model secreting active truncated forms of a processing endoprotease into a bodily fluid.
Furin or paired basic amino acid cleaving enzyme (PACE)1 is a Ca2+-dependent serine protease that processes proteins in the constitutive secretory pathway (1). Furin belongs to a family of subtilisin-like proprotein convertases including kexin (EC 3.4.21.61), PC1/3, PC2, PC4, PC5/6, PACE4 (reviewed in Ref. 1), and PC7/PC8 or lymphoma proprotein convertase (2-5), that play a role in the maturation of proproteins by cleavage at dibasic or tetrabasic sites (6). Unlike PC1/3, PC2, and PC4, which are restricted to endocrine, neural, or testicular germ cells and ovaries, respectively, the furin gene is expressed in most cells and tissues examined (1, 7).
cDNAs cloned from several species show furin to contain prepro-,
catalytic and middle domains, a cysteine-rich region, transmembrane anchor, and cytoplasmic domain (1). Furin is activated by autocatalytic cleavage of its propeptide, presumably at the
-Lys-Arg-Arg-Thr-Lys-Arg1-
site (1, 8). A
membrane-associated protein, it is found mainly in the trans-Golgi
network (TGN) co-localized with the TGN 38 marker protein (9). Some
amount of furin recycles between the cell surface and the TGN (9) in
endosome-like structures (10). So far furin has not been detected in
bodily fluids like blood, nor has the effect of its expression on cell
and organ development been studied in transgenic animals.
Transgenic animals secreting recombinant proteins into milk, blood, urine, or saliva (11) have been generated and differences in recombinant protein modification compared with the human counterpart observed (12). In a pioneering attempt to engineer the post-translational capacity of the mouse mammary gland, we reported enhanced proteolytic maturation of the recombinant human Protein C (rHPC) precursor upon coexpression with furin (13). However, the effect of increased furin concentration on mammary gland development could not be predicted, nor its' intra- and extracellular distribution. Here we demonstrate localization of two heterologous proteins with the endogenous whey acidic protein (WAP) in the mouse mammary gland and secretion of active truncated furin into milk.
The WAP/PACE construct comprising the 2.47-kb human furin
cDNA and 74-base pair 3-untranslated sequences, the four lines of
CD-1 mice transgenic for WAP/HPC (12) and WAP/PACE expressing both
transgenes in the mammary gland have been described (13).
RNA was isolated from tissues of primiparous, F3 generation transgenic and control females on day 10 of lactation using RNAzol (Molecular Research Center). 15 µg of total RNA was fractionated on formaldehyde, 1.2% agarose gels along with RNA markers (Life Technologies) and transferred to GeneScreen Plus membranes (DuPont NEN). A radiolabeled 2.5-kb human PACE cDNA was used to detect mouse furin as they share 94% amino acid homology (14). Blots were hybridized under low stringency conditions, annealing at 62 °C and low stringency washing at 55 °C. Data were corrected for sample loading by ethidium bromide staining and 18 S rRNA detection.
Immunohistochemical Detection of Recombinant ProteinsParaffin-embedded sections of mammary gland from mid-lactation bigenic mice were stained with hematoxylin/eosin or immunostained. Endogenous peroxidase activity was exhausted by immersion in 0.3% hydrogen peroxide for 30 min. Sections were preincubated in 1% bovine serum albumin in phosphate-buffered saline (PBS) with 10% rabbit, horse, or goat serum for the detection of rHPC, furin, or mWAP, respectively. Sections were reacted with a 1:400 dilution of sheep anti-HPC antibody (Affinity Biologicals), a 1:5 dilution of MON 148 antibody (gift of Dr. Van de Ven; Ref. 15) or a 1:800 dilution of rabbit anti-mWAP antibody (gift of Dr. Hennighausen), and developed with biotinylated secondary antibodies at 1:1000 to 1:2000 dilution, an ABC Elite kit (Vector Laboratories), DAB substrate (Sigma), and Mayer's hematoxylin as counterstain. Staining with secondary antibodies alone was negligible. Tissues of at least two animals from all four lines were analyzed.
Preparation of Milk and Western Blot Detection of FurinContinuously bred mice of the F3 and
F4 generations were milked between days 7 and 15 of
lactation after intraperitoneal administration of 0.5 IU oxytocin
(Sigma). Milk was diluted with 2 volumes of PBS, pH 7.4, containing 50 mM EDTA, centrifuged twice at 15,800 × g
for 15 min at 4 °C, and stored at 80 °C. 20 µg of milk
proteins were separated under reducing conditions on 8-16% (Novex) or
10% SDS-polyacrylamide gels and silver stained, or Western blotted with 1:20 to 1:100 dilutions of the MON 139, 148, 150, or 152 anti-furin monoclonal antibodies (15). Horseradish
peroxidase-conjugated goat anti-mouse IgG at 0.5 µg/ml was added and
blots developed by enhanced chemiluminescence (Amersham). rHPC was
detected using the heavy chain-specific 8861 monoclonal antibody, or a
sheep polyclonal antibody. Milk was fractionated essentially as
described (16, 17). Briefly, 100 µl of whole milk containing sucrose at 5% (w/v) was underlaid beneath 1 ml of PBS and spun at 1,500 × g, for 30 min at 22 °C. A lower "skim milk"
fraction was collected, while the upper fat fraction was diluted in 1 ml of PBS and respun. A lower "cream wash" fraction was collected,
while fat globules were dispersed in 1.3 ml of 0.05 M Tris,
pH 7.5, with 0.15 M NaCl, 0.1% (v/v) SDS, 1% (v/v) Triton
X-100, and 1% (w/v) sodium deoxycholate. Globules were chilled to
4 °C and spun at 50,000 × g, for 60 min. The milk
fat globule membrane (MFGM) "supernatant" was collected and the
"MFGM pellet" resuspended in buffer. Fractions were analyzed by 8%
SDS-PAGE.
Fluorometric assays were carried
out essentially as described (18). Defatted milk diluted 1:100 to 1:400
was incubated for 5 min at 37 °C with an equal volume of 100 µM peptide substrate Boc-RVRR-AMC
(N--t-butoxycarbonyl-L-arginyl-L-valyl-L-arginyl-L-arginine-7-AMC; Bachem) in 100 mM HEPES, pH 7.5, containing 1 mM CaCl2 and 0.5% Triton X-100, in a 200-µl
volume. Reactions were terminated by the addition of 100 µl of 15 mM EDTA. 7-Amino-4-methylcoumarin (AMC) liberated by
cleavage was measured with a Perkin-Elmer LS-3 spectrofluorometer, 380 nm excitation, 460 nm emission. The blank sample consisted of substrate
alone, while control milk values were negligible. For kinetic analysis,
duplicate milk samples diluted 1:200 were incubated for 5 min with
Boc-RVRR-AMC at concentrations ranging from 12.5 to 200 µM. Protease activity was assessed by incubating whole
mouse milk from the HPC line 6.4 (12) in a 10:1 ratio with milk from
HPC/PACE line C5.2, for 0-30 min at 37 °C. Milk was then diluted
and processed with PBS, pH 7.4, with 50 mM EDTA to inhibit
further furin activity.
Whole milk, from the HPC line 6.4, 0.9 ml, was incubated with 0.1 ml of milk from line C5.2 HPC/PACE mice for 3 h, at 37 °C. Milk was diluted with 20 ml of 50 mM Tris, 0.15 M NaCl, 2 mM EDTA, 2 mM benzamidine, pH 7.2, and centrifuged at 30,000 × g for 15 min at 4 °C. The defatted milk was re-centrifuged, filtered, and rHPC purified as described (13).
Northern blot
hybridization with the human probe under conditions of low stringency
revealed a 4.2-kb furin transcript in control and transgenic mouse
mammary glands, Fig. 1, corresponding to reports of a
4.5-kb RNA in mouse kidney (7) and a 4.0-kb RNA in other tissues (14).
The signal obtained in the mammary gland was 5-10-fold lower than that
in the liver, salivary gland, and brain (data not shown). The expected
2.5-kb human furin transcript was detected in bigenic mice at levels
about 100-fold higher than endogenous furin.
Detection of Recombinant Proteins in the Mammary Gland
Histologic analyses of the mammary glands of HPC/PACE
bigenic mice did not reveal differences in their gross morphology
compared with control mice, Fig. 2. Transgenic tissues
differed subtly, having less distended alveoli with larger epithelial
cells, as in HPC transgenic mice (19). The distribution of recombinant proteins and endogenous WAP was compared by immunostaining of serial
sections. rHPC was found in the secretory epithelium, and alveolar and
ductal lumina. Unlike the relatively diffuse intracellular staining
pattern of WAP and rHPC, furin showed a more discrete staining pattern.
Unexpectedly, furin was also detected in the lumen, indicating
secretion from the apical surface of epithelial cells. WAP, rHPC, and
furin were detected in all the alveoli and ducts, although some alveoli
stained more intensely than others. Furin and rHPC synthesis appeared
to be regulated like WAP, being present inside the epithelial cells
lining collapsed milked-out alveoli, although predominantly in the
lumina of milk-distended alveoli. Control mouse tissue was stained
neither by furin- nor rHPC-specific antibodies.
Characterization of Furin Secreted in Milk
The furin-specific
MON 148 antibody (15) detected a protein of approximately 80 kDa in
bigenic mouse milk, which was absent in control milk (Fig.
3A). Higher levels were detected in lines C1.2, C2.2, and C5.2, than in C4.1. Trace polypeptides of approximately 150 kDa were also detected. A 141-kDa membrane-associated form of furin
was recently reported in neural lobe secretory vesicles (20). MON 152 which is specific for human furin also detected the 80-kDa protein
(Fig. 3B). The enzyme was not recognized by MON 150 and MON
139, indicating removal of the propeptide and C-terminal region,
respectively (Fig. 4). These results are consistent with
truncation at the hydrophobic transmembrane domain, resulting in
secretion of an 80-kDa form. The minor protein species of approximately 65 kDa probably arises from additional cleavage(s) in the cysteine-rich region (21, 22). Selective inclusion of furin in the MFGM was not
observed upon fractionation of milk (Fig. 3C), while traces of a 90-kDa protein detected upon prolonged exposure may represent full-length furin from sloughed-off epithelial cells. A rough estimate
of 81-325 µg/ml furin in the milk was obtained by comparison with
Coomassie Blue-stained gels and Western blots of soluble furin secreted
by CV-1 cells (data not shown).
Activity of Secreted Furin
Release of AMC from a fluorogenic tetrapeptide substrate, Boc-RVRR-AMC, indicated the presence of active furin in milk. The activity of furin varied in four lines of mice correlating with mRNA (13) and protein levels (Table I and Fig. 3A). Secreted furin cleaved the substrate with an average Km of 32.3 ± 0.85 µM, correlating with the reported values of 27 and 26 µM for furin secreted from VV:hFUR (23) and hFUR713t-infected BSC40 cells (18), respectively, and indicating similarity of the serine protease domains.
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In HPC/PACE bigenic mice, rHPC was processed to the mature protein
(13), unlike rHPC from HPC transgenic mice, which consisted mainly of
the single chain precursor with propeptide (12). Incubating the milk of
bigenic and HPC mice together resulted in a reduction of the amount of
rHPC single chain (Fig. 5A and Fig. 4).
Incubation of milk from HPC mice alone did not alter the
electrophoretic pattern of rHPC, but trace amounts of single chain
present in HPC/PACE milk disappeared. rHPC purified from a mixture of
HPC/PACE and HPC milk after incubation showed a marked reduction in the amount of precursor (Fig. 5B). Amino acid sequencing
confirmed site-specific cleavage of the propeptide.
Normal cells express furin at low levels and the enzyme is
ubiquitously distributed (7). Expression of furin in genetically engineered cells or animals at a great excess beyond the basal level
deviates from the physiological norm and may be toxic. Toxicity of
furin has been reported in transfected cells (24), probably due to
broadened specificity. The furin gene was also up-regulated 5-10-fold
in primary human non-small cell lung carcinomas (7), while PC7/PC8 has
been implicated as a target for chromosomal translocation and
deregulation (5). Various proteins involved in mammary growth and
differentiation like insulin (25), insulin-like growth factor (6),
insulin pro-receptor (26), transforming growth factor-1
(27), and parathyroid hormone-related protein (22) are also processed
by furin. Stromelysin-3, a metalloprotease involved in mammary tissue
remodeling, was activated by furin in cells and in solution (29). Thus,
undesirable effects following the expression of an additional protease
could not be excluded. We show here that although transgene transcripts
were highly expressed, mammary gland gross morphology was similar in
normal and transgenic animals. Mammary development was not impaired,
nor were tumors observed in mice from any line for up to 2 years of age
and over several generations, implying that increased furin expression in mammary epithelial cells was not associated with transformation. Our
results also do not implicate secreted furin in tissue remodeling.
Two mechanisms could possibly explain our data. First, large amounts of
the specific substrate, rHPC, may limit access of furin to other
proteins. The presence of furin and rHPC in the same region of the
mammary gland and in the same alveoli would support this argument. Our
unique observation of the co-localization of two foreign proteins
suggests the coordinated regulation of expression and protein synthesis
of two cointegrated transgenes in the mammary gland. The two transgenes
under control of the 4.1-kb WAP promoter also mimicked the pattern of
synthesis of endogenous WAP, supporting reports of the simultaneous
synthesis of endogenous milk proteins and a heterologous protein under
the control of the -lactoglobulin promoter (30). Although several multigenic animal models have been generated, the site(s) of synthesis and cellular distribution of foreign proteins were not established (31,
32). The amount of fully assembled human fibrinogen hexamer secreted
into milk of
-lactoglobulin/fibrinogen transgenic mice was reported
to range from 10 to 100% (32). As coordinate synthesis of the
-,
-,
-subunit chains is required for the correct assembly of human
fibrinogen, partial assembly may imply a heterogeneous pattern of
synthesis in some lines.
The second mechanism assumes secretion of excess furin from epithelial cells (Fig. 4). Secretion from transfected cells (23, 33, 34) has been suggested as a mechanism to regulate the amount of intracellular enzyme (35) and we also detected furin in milk. So far furin had not been detected in any bodily fluid in normal or pathological states, probably due to the low sensitivity of existing methods. This should be considered when generating animals expressing furin in the liver, as the secreted protein could be directed to the circulation. We had expected furin to be shed from the apical plasma membrane of mammary cells in fat globules, but did not detect full-length protein in the MFGM fraction. Unlike the cystic fibrosis transductance regulator protein found predominantly in the milk fat of transgenic mice (19), this was not the main route of furin secretion. Finding truncated furin in all fractions of milk suggested secretion along with the milk proteins. Propeptide removal probably occurred in the endoplasmic reticulum, followed by targeting to the TGN in the presence of the cytoplasmic tail (9, 33). Cleavage of the acidic signal crucial for TGN retention then resulted in secretion (28, 29), implying that C-terminal processing of furin occurs in normal, untransformed mammalian cells.
The activity of secreted furin provided further evidence of propeptide
processing, as propeptide removal was necessary for enzyme activation
(9) and the presence of propeptide on a furin mutant led to loss of
activity (36). In milk up to 40,000 units/ml active furin which
functioned as a protease in the maturation of the rHPC precursor was
detected, unlike the PACE-Sol mutant which was unable to process vWF in
the medium of COS-1 cells (37). We therefore conclude that both the
intracellular and truncated extracellular forms are active and process
the rHPC precursor in epithelial cells as well as in milk (Fig. 4).
Similarly, Prieto et al. (1995) described the presence of
active human 1,2-fucosyltransferase in the milk of mice (38). Thus,
it is possible to produce significant amounts of secreted forms of
intracellular enzymes in milk.
Our results should encourage others to augment the processing of endogenous and heterologous proteins in transgenic animals. It will not be necessary to process incompletely modified recombinant proteins in vitro, instead this can be done simultaneously in vivo. The intra- and extracellular presence of furin allows for multiple interactions with its substrate, thus removing temporal and spatial constraints on proprotein processing and highlighting further advantages of protein production in transgenic animal bioreactors.
We thank Drs. R. J. Kaufman and A. Rehemtulla for the human PACE/furin cDNA clone, Dr. W. J. M. van de Ven for the generous gift of the MON 139, 148, 150, and 152 antibodies, Dr. L. Hennighausen for the anti-WAP antibody, Dr. C. Haudenschild for help with immunohistochemistry, and Dr. W. Garten for partially purified soluble furin from CV-1 cells. We are grateful to Dr. W. N. Drohan for continued support.