(Received for publication, December 24, 1996, and in revised form, March 13, 1997)
From the Department of Medical Biochemistry and
Biophysics and the ** Microbiology and Tumor Biology Center, Karolinska
Institutet, S-171 77 Stockholm, Sweden and the § Department
of Dermatology, Karolinska Hospital, S-171 76 Stockholm, Sweden
The epithelia constitute a major barrier to the environment and provide the first line of defense against invading microbes. Antimicrobial peptides are emerging as participants in the defense system of epithelial barriers in general. Originally we isolated the human antimicrobial peptide LL-37 from granulocytes. The gene (CAMP or cathelicidin antimicrobial peptide) coding for this peptide belongs to the cathelicidin family, whose members contain a conserved pro-part of the cathelin type. The human genome seems to have only one gene of this family, whereas some mammalian species have several cathelicidin genes. In the present work we demonstrate up-regulation of this human cathelicidin gene in inflammatory skin disorders, whereas in normal skin no induction was found. By in situ hybridization and immunohistochemistry the transcript and the peptide were located in keratinocytes throughout the epidermis of the inflammatory regions. In addition, the peptide was detected in partially pure fractions derived from psoriatic scales by immunoblotting. These fractions also exhibited antibacterial activity. We propose a protective role for LL-37, when the integrity of the skin barrier is damaged, participating in the first line of defense, and preventing local infection and systemic invasion of microbes.
Epithelia provide a barrier between the body and the environment. In addition, the epithelial cells have an active immunological role with antigen processing and presentation and production of cytokines and defense effector molecules such as microbicidal peptides. Thus, the epithelia mediate an active protection against invading microbes (1).
Several broad spectrum microbicidal peptides have been identified in
mammalian mucosal epithelium; bovine tracheal mucosa produces a
-defensin, TAP (tracheal antimicrobial peptide) (2), paneth cells of
the gastrointestinal mucosa of human and mouse synthesize defensins (3,
4), and another
-defensin, LAP (lingual antimicrobial peptide) is
expressed by bovine tongue epithelial cells (5). Thus, peptide
antibiotics appear at the surface epithelium where they are likely to
act as key components in the first line of defense and in the wound
healing process (5). So far, all mammalian antimicrobial peptides
identified at the mucosal interface belong to the defensin family.
Defensins are cysteine-rich peptides folded in
-pleated sheets with
a broad activity against bacteria, enveloped viruses, fungi, and
parasites (6).
We have isolated a clone for a novel human antibacterial peptide and
named the putative peptide FALL-39 (7). Recently the mature active
peptide LL-37 (two amino acids shorter at the N terminus than the
putative peptide) was isolated from granulocytes and characterized
(amino acid sequence is shown in Fig. 2B) (8). The
preproprotein of LL-37 has also been named human CAP18 by another group
(9). In contrast to the defensins, LL-37 is a cysteine-free peptide
that can adopt an amphipathic -helical conformation. The
preproprotein belongs to the cathelicidin protein family. The common
nominator of this protein family is a well conserved proregion of
cathelin type, whereas the C-terminal domain is represented by highly
variant antibacterial peptides (10). A pronounced variation is also
noticed in different numbers of cathelicidin genes between mammalian
species. So far, prepro-LL-37 is the only human cathelicidin
characterized. The gene is expressed in bone marrow and testis, and the
peptide and its proform have been localized in granulocytes (8, 11). In
addition, we have detected LL-37 together with several other
antibacterial peptides in human wound and blister fluids (12).
To investigate antibacterial activity at human epithelial surfaces we initiated studies on the expression of LL-37 in human skin and in inflammatory dermatoses. The RT-PCR1 experiment showed that the gene is not expressed in normal skin but interestingly in lesional psoriasis and challenged nickel allergy, indicating an induction of LL-37 in these skin disorders. We have confirmed the induction on cellular level by in situ hybridization and immunohistochemistry in various distinct inflammatory skin diseases such as psoriasis, subacute lupus erythematosus, dermatitis herpetiformis, atopic dermatitis, and nickel contact hypersensitivity. In these diseases the expression of the gene for LL-37 is induced in keratinocytes within the inflammatory regions, whereas in normal skin the peptide is not found in epidermis. In addition, we have detected LL-37 in partially purified fractions from psoriatic scales. The peptide is also seen in chromatographic fractions derived from normal skin, where LL-37 most likely originates from granulocytes. Our results show that LL-37 is induced during inflammation in human skin, which is consistent with a protective role for LL-37 as an effector molecule in the first line of defense.
Punch biopsies were obtained both from normal skin of healthy volunteers and untreated patients with different inflammatory skin conditions; psoriasis, nickel allergy (before and after challenge), subacute lupus erythematosus, dermatitis herpetiformis, and atopic dermatitis (Table I). For immunohistochemistry the biopsies were fixed in formalin and embedded in paraffin, but biopsies for in situ hybridization were frozen directly.
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Total RNA was extracted from skin biopsies using RNAzol
B (Biotecx Laboratories, Inc.) according to the instructions from the
manufacturer. The RNA was denaturated at 90 °C for 5 min before the
first strand cDNA synthesis and then chilled on ice. For the first
strand synthesis random hexamer primers and 200 units of Moloney murine
leukemia virus reverse transcriptase (Life Technologies, Inc.) were
used in a reaction volume of 20 µl using recommended conditions. The
reaction was incubated at 40 °C for 45 min, heated at 95 °C for 5 min, then diluted to 100 µl with water, and stored at 20 °C
until used for PCR. The primers 5
-GAAGACCCAAAGGAATGGCC and
5
-TCAGAGCCCAGAAGCCTGAG were used in the PCR reactions and were
directed to the signal sequence and the 3
-untranslated region of the
LL-37 mRNA, respectively. Included in the PCR reactions were
primers directed to glyceraldehyde-3-phosphate dehydrogenase (G3PDH;
CLONTECH) to monitor the cDNA synthesis. These
primers (at 0.5 µM) and 1 µl of the synthesized
cDNA as template were utilized for PCR amplification with the
following thermal cycle profile: 94 °C for 3 min; 30 cycles of
60 °C for 1 min, 72 °C for 1 min, and 94 °C for 1 min; and
finally an extension step of 72 °C for 7 min. Analysis of the
reaction mixtures was done in 1.2% agarose gel, and the amplified DNA
was blotted onto a Hybond N nylon filter (Amersham) according to
standard procedure (13). The filter was prehybridized 4 h in
6 × standard saline citrate (SSC)/5 × Denhardt's
solution/1% SDS/denaturated salmon sperm DNA 100 µg/ml at 64 °C.
The hybridization was overnight with a probe specific for prepro-LL-37
in the same condition as the prehybridization. A second hybridization
was performed with the G3PDH probe (CLONTECH) on
the same filter. After both hybridizations the filter was washed
several times, finishing with 0.1 × SSC at 64 °C for 20 min.
The probes were 32P-labeled using a Rediprime labeling kit
(Amersham). Autoradiography was used to record the result.
The cDNA insert coding for prepro-LL-37 (before called FALL-39 (7)) was isolated and cleaved with the restriction enzyme HpaII. A 179-bp fragment (bold underlined in Fig. 2A) was subcloned into the ClaI site of pBluescript-KS vector (Stratagene). The orientation and the sequence of the fragment was confirmed by the dideoxy chain termination method with a Sequenase kit (U. S. Biochemical Corp.). Digoxigenin-labeled cRNA probes were prepared by a DIG RNA labeling kit Sp6/T7 (Boeringer Mannheim) by T7 and T3 RNA polymerases.
In Situ Hybridizations5-µm-thick frozen sections were used for hybridization with digoxigenin-labeled cRNA probes in a humid chamber as described previously (14). Parallel sections from each biopsy were hybridized with sense and antisense cRNA probes specific for LL-37, respectively.
ImmunohistochemistryFormalin-fixed and paraffin-embedded biopsies were sectioned at 4 µm. To quench endogenous peroxidase activity, deparaffinized, rehydrated sections were treated with 0.3% H2O2 in methanol for 30 min at room temperature. After rinsing in phosphate-buffer saline the sections were digested with 0.1% trypsin (Sigma) at 37 °C for 30 min. All sections were stained according to the indirect peroxidase method (15) utilizing a Vectastain ABC kit elite (Vector Laboratories) and following the instructions of the manufacturer. Briefly, the sections were incubated with 1.5% normal goat serum for 20 min at room temperature and then incubated overnight at 4 °C with the polyclonal antibody against LL-37 (1:500 dilution). Control sections from the same tissues were similarly processed and analyzed during the experiment except that no LL-37 antibody was added. To ascertain the specificity of the immunostaining, immunoadsorption was performed in a solution of 500 µl with the anti-LL-37 (dilution 1:500) and 5 µl of LL-37 in different concentrations. The mixture was incubated at room temperature for 3 h prior to immunohistochemical analyses. Final concentrations of the peptide in the reactions were 20 µg/ml, 200 ng/ml, and 2 ng/ml. Control sections were processed according to the same protocol, except that no peptide was added to adsorb the antibody.
Extraction and Chromatography of Psoriatic Scales and Normal SkinPsoriatic scales were collected (0.85 g) and extracted in 60% aqueous acetonitrile containing 1% trifluoroacetic acid overnight at 4 °C. The extraction mixture was then centrifugated at 21780 × g for 20 min, and the supernatant was collected and lyophilized. The lyophilized material was dissolved in 0.1% trifluoroacetic acid and applied on a Sep-Pak C18 (Waters) equilibrated in 0.1% trifluoroacetic acid. The Sep-Pak was then washed with 10% aqueous acetonitrile in 0.1% trifluoroacetic acid, and the material that bound to the Sep-Pak was eluted with 80% aqueous acetonitrile in 0.1% trifluoroacetic acid and lyophilized. Reversed-phase chromatography of the eluted material was performed on a Source 15 RPC column (1.6 × 10 cm; Pharmacia) equilibrated in 0.1% trifluoroacetic acid, at a flow of 6 ml/min and with a gradient of acetonitrile. In this preparative HPLC step a Waters 650 pump and a Waters detector (Model 481) were utilized.
Normal human abdominal skin (12 g) was obtained from reduction plastic
surgery. After removal of all fat the skin piece was washed in 0.9%
NaCl. Before freezing at 70 °C, approximately 1 cm was removed
from the edges of the skin piece, which was subsequently sectioned at
50 µm, extracted, and purified on Sep-Pak and HPLC as described
above.
Detection of LL-37 immunoreactivity in the chromatographic fractions was performed with a dot-blot assay using a rabbit polyclonal antibody specific for LL-37 that was obtained by a standard immunization scheme using 100 µg of synthetic peptide mixed with Freund's complete adjuvant as described previously (8).
Western Blot AnalysisFractions that showed immunoreactivity in the dot-blot assay were selected for separation on discontinuous SDS-polyacrylamide gel electrophoresis using 16.5% Tris-Tricine Ready Gel (Bio-Rad). The material in the gels was blotted onto nitrocellulose filters (Hybond-C, Amersham Corp.) by electrophoretic transfer as described previously (16). Immunoreactivity was detected with the LL-37-specific antibody (see above in immunoassay). The second antibody was an anti-rabbit IgG conjugated with alkaline phosphatase, obtained from Sigma. The filter was stained for enzyme activity in 100 mM Tris-HCl, pH 8.5, 100 mM NaCl, and 5 mM MgCl2 containing 4-nitro blue tetrazolium chloride (0.2 mg/ml) and 5-bromo-4-chloro-3-indolyl phosphate (0.1 mg/ml), both purchased from Boehringer Mannheim.
Antibacterial AssayThin plates (1 mm thick) were poured with LB (Luria Bertani) broth supplemented with medium E (17), 1% agarose, and approximately 6 × 104 cells/ml of either one of the two test bacteria strains, Escherichia coli D21 and Bacillus megaterium Bm11. Small wells (diameter, 3 mm) were punched in the plates, and 3-µl test samples were applied in the wells. After overnight incubation at 30 °C, the diameters of inhibition zones were recorded with a ruler.
From three individuals, five biopsies were
taken and RNA was prepared. Two biopsies were taken from a psoriatic
patient, one was taken from a psoriatic lesion, and another was taken
from an uninvolved region. From a patient with nickel contact allergy one biopsy was obtained from healthy skin and one was taken from a
provoked nickel hypersensitivity reaction. In addition, one biopsy was
obtained from normal skin of a healthy volunteer. The RNA from each
biopsy was used separately for cDNA synthesis. The cDNA was
utilized as templates in the PCR reactions. Two specific primer pairs
were used for detection of transcripts. One pair was directed to the
LL-37 cDNA, and the other pair was directed toward G3PDH cDNA;
the latter served as control for efficient cDNA synthesis. The PCR
reactions were size fractionated on an 1.2% agarose gel, and bands of
expected size (983 bp) were detected in all lanes for the control
(G3PDH), whereas a band of 547 bp corresponding to LL-37 cDNA was
detected only in the sample from the psoriatic lesion and challenged
nickel allergy. The identity of amplified bands was confirmed by high
stringency Southern blot hybridization with specific probes for LL-37
and G3PDH cDNA, respectively (Fig. 1). These results
show an induction of LL-37 in psoriasis and nickel allergy. The
prominent bands for the control G3PDH may reflect the
hyperproliferative nature of keratinocytes in these conditions.
Cellular Localization by in Situ Hybridization and Immunohistochemistry
To determine cellular localization for the
induction of LL-37 observed by RT-PCR, we performed in situ
hybridizations on samples on lesional psoriasis and challenged nickel
allergy. The cRNA probes used correspond to the main LL-37 coding part
and the 3-untranslated region (Fig. 2). In both
conditions (psoriasis and nickel allergy) there was abundant signal for
LL-37 mRNA in keratinocytes throughout the epidermis (Fig.
3, A and E), whereas no
hybridization signal was detected in the epidermis of healthy skin (not
shown). Control slides hybridized with the sense cRNA probe were
negative (Fig. 3B for psoriasis).
In accordance with data obtained by in situ hybridizations, immunohistochemical analyses demonstrated strong staining for LL-37 peptide in epidermal keratinocytes in psoriasis and nickel allergy reaction (Fig. 3, C and F). Furthermore, a similar pattern of LL-37 immunoreactivity in keratinocytes was found in various dermatoses such as subacute lupus erythematosus (Fig. 3D), dermatitis herpetiformis (not shown), and atopic dermatitis (Fig. 3I). Thus, by extending our studies comprising distinct inflammatory disorders, our results clearly show that LL-37 is consistently induced in skin epithelium in association with inflammation irrespective of the underlying pathogenic mechanism. In addition, confirming previous results (8) and serving as an internal positive control, there was abundant immunoreactivity for LL-37 in granulocytes in all samples of both healthy and affected skin (Fig. 3J, affected skin). When LL-37 was used to absorb the antibody, immunostaining decreased in a dose-dependent manner as the concentration of the peptide was increased, and at 20 µg/ml peptide concentration the staining was completely abolished (Fig. 3H).
Chromatography and Detection of LL-37 in Psoriatic Scales and Normal SkinPsoriatic scales (0.85 g) and normal skin
(12 g) were extracted and purified on Sep-Pak as described
under "Experimental Procedures." Lyophilized material eluted from
Sep-Pak, 5.5 mg derived from the psoriatic scales, and 12.8 mg from the
normal skin were dissolved in 0.5 and 1.2 ml of 0.1% trifluoroacetic
acid, respectively. Chromatography of each sample was performed on an
HPLC reversed-phase column equilibrated in 0.1% aqueous
trifluoroacetic acid, and the elution was with a five-step gradient of
acetonitrile in 0.1% trifluoroacetic acid: 1) from 0 to 15% over 5 min, 2) from 15 to 40% over 25 min, 3) isocratic at 40% for 10 min,
4) from 40 to 65% over 25 min, and 5) from 65 to 80% over 10 min.
Fig. 4 shows the chromatographic profiles of the
material derived from both psoriatic scales (Fig. 4A) and
normal skin (Fig. 4B). The collected fractions were
lyophilized and redissolved in 100 µl of water for psoriatic scales
and 250 µl for normal skin. To monitor the presence of LL-37
immunoreactivity, 2 µl of the fractions were used for dot-blot
immunoassay. Several positive fractions were detected both in the
psoriasis material and in the normal skin preparation. The fractions
with the most pronounced immunoreactivity were further analyzed by
Western blot analysis. The results are shown in Fig. 5
for psoriatic scales and normal skin fractions number 33, 34, and 35, respectively. In fraction 35 from the psoriatic scales a clear band
corresponding to LL-37 was detected, whereas faint bands for LL-37 were
seen in the other fractions. Furthermore, immunoreactivity was also
present in the high molecular weight regions. This immunoreactivity
could originate from the unprocessed proform, binding, or aggregation
of the peptide with larger proteins. Another possible explanation is
that the antibodies cross-react with some other proteins.
Antibacterial Activity
Fractions 33-35 analyzed by Western
blot were also tested for antibacterial activity. From each fraction
equal amounts of protein material (20 µg) was loaded into the wells
of the assay plate and for comparison known amounts of synthetic LL-37
were included. Fig. 6 shows that all these fractions
have antibacterial activity. Elevated activity was detected in the
material derived from the psoriatic scales as compared with normal
skin. Notably, the highest antibacterial activity was recorded in
fraction 35 of the psoriatic scales, which corresponds to the strongest
band for LL-37 in the Western blot. However, the strength of activity is comparable with µg of LL-37, whereas the band intensity on Western
is weaker, indicating that this fraction contains additional components, enhancing the antibacterial activity.
Taken together, our results demonstrate the induction of the gene coding for LL-37 on both mRNA and protein levels in human epidermis during inflammation.
Several microbicidal peptides are expressed by surface epithelial cells in mammals. The emerging concept is that these peptides contribute to the protective barrier of the epithelia by killing invading microorganisms (5, 18). Human skin is the major epithelial barrier between the body and the environment and functions as an active immune organ (19). Antimicrobial peptides are rapidly activated and have a broad spectrum activity against microbes (20) and may contribute to the first line of defense in skin epithelia. To find out if the recently discovered human antibacterial peptide LL-37 is a part of the skin immune system, we analyzed the expression of the corresponding gene in normal skin and in inflammatory skin diseases. The present work demonstrates for the first time induction of an antimicrobial peptide in human skin during inflammation. Our results are consistent with a protective role for LL-37 against microbial invasion through a disrupted skin barrier working together with migratory inflammatory cells.
We initiated our studies with RT-PCR that showed an induction of LL-37 in two inflammatory skin disorders, psoriasis, and challenged nickel allergy but no expression in healthy skin (Fig. 1). By a series of in situ hybridizations and immunohistochemistry, the up-regulation of the gene coding for LL-37 was confirmed and localized to keratinocytes. The tissue sections were from normal skin and different inflammatory dermatoses: psoriasis, nickel contact hypersensitivity, subacute lupus erythematosus, dermatitis herpetiformis, and atopic dermatitis. In all these inflammatory dermatoses a pronounced induction in keratinocytes for LL-37 is noted, whereas in healthy skin no signal was detected in the epidermis.
To further evaluate the induction and also screen for antibacterial activity, protein extracts were prepared from psoriatic scales and healthy skin. After separation of the extracts on HPLC, several chromatographic fractions contained antibacterial activity. In some of these fractions both from psoriatic scales and healthy skin, LL-37 immunoreactivity could be detected by a dot-blot assay. To track this immunoreactivity a Western blot analysis was performed and a clear band was detected in one psoriatic fraction, representing LL-37. In the other fractions shown in Fig. 5 only faint bands in the same region were found. The detection of faint bands on the Western blot of LL-37 in normal skin is not in agreement with the results obtained by the other detection methods (RT-PCR, in situ hybridization, and immunohistochemistry). Our conclusion is that the peptide detected in normal skin originates from residing granulocytes that harbor the peptide in their vacuoles. Another explanation for faint bands on Western blot is that trauma during the surgical procedure of the reduction plastic surgery may induce LL-37.
The fractions that contained LL-37 immunoreactivity were analyzed for antibacterial activity together with a dilution series of synthetic LL-37. Fraction 35 from the psoriatic scales, which contains the highest amount of LL-37 as determined by band strength on Western blot, also exhibited the highest antibacterial activity. Because 20 µg of dry weight of fraction 35 were used in the antibacterial assay as well as on Western blot, the zone diameter as compared with the reference of LL-37 is larger than expected if the activity is solely derived from LL-37. However, this fraction is not purified to homogeneity, and the antibacterial activity must be dependent also on additional components that enhance the bactericidal effect in this fraction.
Previously, we have localized the tissue-specific expression of the gene for LL-37 to testis and bone marrow (7). We have also characterized and sequenced the complete CAMP2 gene (8). In the promoter region we identified potential binding sites for the transcription factors, acute phase response factor and nuclear factor for interleukin-6 expression, indicating that these transcriptions factors are recruited when the gene is turned on. Interleukin-6 (IL-6) regulates the activation of these two transcription factors (21, 22), and accordingly we suggested that this cytokine is an important modulator of the CAMP gene expression. In fact, this cytokine plays a crucial role in local and systemic inflammation, acting as a major alarm inducer during infection and injury. IL-6 and its corresponding receptor are known to be synthesized by keratinocytes (23). In addition, IL-6 is expressed at high levels in lesional psoriatic skin in contrast to normal skin and has been proposed to affect the function of dermal inflammatory cells (24). One of the effects of IL-6 might be the up-regulation of the CAMP gene that we have documented here in five different inflammatory dermatoses. Consequently, this induction could enhance the antimicrobial defense armament of the disrupted barrier and thus provide an important shield against systemic invasion.
We thank Berit Olsson for the antibody against LL-37, Elisabeth Henriksson for technical assistance, and Carina Palmberg for help with the drawings. Hans Jörnvall and Viktor Mutt are acknowledged for helpful discussions and advice.