Dermatology: Practical and Conceptual


Research  |  Dermatol Pract Concept 2017;7(4):2 3

DERMATOLOGY PRACTICAL & CONCEPTUAL
www.derm101.com

Cell junction protein armadillo repeat gene deleted 
in velo-cardio-facial syndrome is expressed in 

the skin and colocalizes with autoantibodies of 
patients affected by a new variant of endemic 

pemphigus foliaceus in Colombia
Ana Maria Abreu-Velez1, Hong Yi2, Michael S. Howard1

1 Georgia Dermatopathology Associates, Atlanta, GA, USA

2 Robert P. Apkarian Integrated Electron Microscopy Core, Emory University Medical Center, Atlanta, GA, USA

Key words: endemic pemphigus foliaceus, autoimmunity, cell junctions, ARCVF, skin

Citation: Abreu-Velez AM, Yi H, Howard MS. Cell junction protein armadillo repeat gene deleted in velo-cardio-facial syndrome 
is expressed in the skin and colocalizes with autoantibodies of patients affected by a new variant of endemic pemphigus foliaceus 
in Colombia. Dermatol Pract Concept 2017;7(4):3-8. DOI: https://doi.org/10.5826/dpc.0704a02

Received: June 7, 2017; Accepted: July 31, 2017; Published: October 31, 2017

Copyright: ©2017 Abreu-Velez et al. This is an open-access article distributed under the terms of the Creative Commons Attribution 
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are 
credited.

Declaration of sources of funding: Our work was performed with funding from Georgia Dermatopathology Associates and Mineros SA, 
El Bagre, the Hospital Nuestra Señora del Carmen, El Bagre; and El Bagre Municipal Office, Colombia, South America.

Competing interests: The authors have no conflicts of interest to disclose.

All authors have contributed significantly to this publication.

Corresponding author: Ana Maria Abreu-Velez, MD, PhD, Georgia Dermatopathology Associates, 1534 North Decatur Rd NE, Suite 206, 
Atlanta, GA 30307-1000, USA. Tel. (404) 371-0027; Fax: (404) 371-1900. Email: abreuvelez@yahoo.com.

Background: We previously described a new variant of endemic pemphigus foliaceus in El Bagre, 
Colombia, South America (El Bagre-EPF, or pemphigus Abreu-Manu). El Bagre-EPF differs from other 
types of EPF clinically, epidemiologically, immunologically and in its target antigens. We reported the 
presence of patient autoantibodies colocalizing with armadillo repeat gene deleted in velo-cardio-facial 
syndrome (ARVCF), a catenin cell junction protein colocalizing with El Bagre-EPF autoantibodies in 
the heart and within pilosebaceous units along their neurovascular supply routes. Here we investigate 
the presence of ARVCF in skin and its possibility as a cutaneous El Bagre-EPF antigen.

Methods: We used a case-control study, testing sera of 45 patients and 45 controls via direct and 
indirect immunofluorescence (DIF/IIF), confocal microscopy, immunoelectron microscopy and im-
munoblotting for the presence of ARVCF and its relationship with El Bagre-EPF autoantibodies in the 
skin. We also immunoadsorbed samples with desmoglein 1 (Dsg1) ectodomain (El Bagre-EPF antigen) 
by incubating with the positive ARVCF samples from DIF and IIF.

Results: ARVCF was expressed in all the samples from the cases and controls. Immunoadsorption 
with Dsg1 on positive ARVCF immunofluorescence DIF/IIF cases showed that the immune response 
was present against non-desmoglein 1 antigen(s). Overall, 40/45 patients showed colocalization of 
their autoantibodies with ARVCF in the epidermis; no controls from the endemic area displayed co-
localization.

Conclusions: We demonstrate that ARVCF is expressed in many areas of human skin, and colocalizes 
with the majority of El Bagre-EPF autoantibodies as a putative antigen.

ABSTRACT



4 Research  |  Dermatol Pract Concept 2017;7(4):2

tures, and whether we could further confirm colocalization of 

El Bagre-EPF autoantibodies with ARVCF in the skin.

Materials and Methods

A human quality assurance review board approved the stud-

ies at the Hospital Nuestra Señora del Carmen in El Bagre, 

and all participants provided signed consent. We tested 45 

patients affected by El Bagre-EPF, and 45 controls from the 

endemic area matched by age, sex, demographics, comor-

bidities, and work activities. All of the tests were performed 

in both cases and controls. The patients and controls were 

evaluated by hematoxylin and eosin (H&E) histology, DIF, 

IIF, confocal microscopy (CFM), indirect immunoelectron 

microscopy (IEM) immunoblotting (IB), by immunoprecipita-

tion (IP) and by ELISA. Only patients meeting diagnostic cri-

teria for El Bagre-EPF were included; specifically, they had to 

display clinical and epidemiologic features described for this 

disease; live in the endemic area; and have serum displaying 

intercellular staining (ICS) between epidermal keratinocytes 

and to the basement membrane zone (BMZ) of the skin via 

either DIF or IIF using fluorescein isothiocyanate (FITC) con-

jugated monoclonal antibodies to human total IgG or IgG4, 

as described elsewhere [5-9]. Further, each patient had to be 

positive by IB for reactivity against Dsg1 [6], as well as for 

plakin molecules; each patient’s serum immunoprecipitated 

a Concanavalin A (Con A) affinity-purified bovine tryptic 45 

kDa fragment of Dsg1 [14]; and each patient’s serum had to 

yield a positive result using an ELISA test when screening for 

autoantibodies to pemphigus foliaceus (PF) antigens [15].

DIF and IIF: We performed our DIF and IIF as previously 

described [8,9].

DIF: In brief, we incubated a 4 μm thickness frozen skin 

section using PBS with 0.1% Triton X-100 and 1% normal 

goat serum for five minutes for partial permeabilization, to 

detect cytoplasmic, nuclear, and membrane binding putative 

antigens, and for blocking non-specific staining. The slides 

were then washed with PBS [8,9]. The nuclei of the cells 

were counterstained with 4,6-diamidino-2-phenylindole 

(DAPI, Pierce; Rockford, IL, USA). We used antibodies to 

ARVCF, source guinea pig, Cat. no. GP155; Progen Bio-

technik (Heidelberg, Germany). For its secondary, we used 

Alexa Fluor®555 goat-anti-guinea pig (Molecular Probes Life 

Technologies/ThermoFisher Scientific; Waltham, MA, USA). 

All samples were run with positive and negative controls. We 

classified our findings as negative (-), weakly positive (+), 

moderately positive (++) and strongly positive (+++). For IIF, 

our substrate tissue included human, bovine, rat and mouse 

skin. Written consents were obtained from all patients, and 

Institutional Review Board permission was obtained from 

the Hospital Nuestra Señora de El Carmen, in El Bagre, 

Colombia.

Introduction

Endemic pemphigus foliaceus (EPF) is an autoimmune blister-

ing disease characterized by the presence of autoantibodies 

(primarily to desmoglein 1 [Dsg1]). On direct immunofluores-

cence (DIF) and indirect immunofluorescence (IIF), the EPF 

autoantibodies display intercellular staining (ICS) between 

epidermal keratinocytes [1-3]. In Brazil, EPF is titled fogo sel-

vagem (FS) and principally affects children and young adults. 

EPF has also been documented in rural areas of South and 

Central America (Argentina, Bolivia, El Salvador, Paraguay, 

Peru and Venezuela) [1-3]. One additional variant has been 

described in Tunisia, Africa [4].

We previously described a new variant of EPF in El Bagre, 

Colombia, South America (El Bagre-EPF, or pemphigus 

Abreu-Manu). El Bagre-EPF differs from other types of EPF 

because it affects predominantly 30- to70-year-old or older 

males, and a few peri/postmenopausal females [5-7]. The 

patients are primarily miners, who also work in agricultural 

activities. The patients have autoantibodies to dermal eccrine, 

sebaceous and Meibomian glands, and their neurovascular 

bundles; to cardiac molecules; to Pacinian receptors and 

other cutaneous neural receptors; and to tarsal muscles and 

to other structures [8-10]. For over two decades, we have fol-

lowed the El Bagre-EPF patients [5-7,8-10]. The disease was 

originally thought to be a new focus of Brazilian EPF with 

some differences [19]; however, we later documented it as a 

new and unique disease, resembling Senear-Usher syndrome. 

We documented El Bagre EPF to have a unique autoimmune 

response due to environmental and genetic factors [10-14]. 

We also previously reported that one-third of the El Bagre-

EPF patients present with a systemic form, as observed in 

systemic lupus erythematosus [10-15].

We previously reported the colocalization of El Bagre-EPF 

patient autoantibodies with armadillo repeat gene deleted 

in velo-cardio-facial syndrome (ARVCF) in cardiac tissue, 

as well as within pilosebaceous units along their neurovas-

cular supply routes [9,11]. ARVCF is an adhesion molecule 

of the catenin-like protein family that is one of the mutated 

molecules in the disease called velo-cardio-facial syndrome 

(VCFS). VCFS, along with DiGeorge syndrome (DGS), and 

conotruncal anomaly face syndrome are part of the disease 

complex termed chromosomal microdeletions dissecting 

(CMD): del22q11 syndrome [11-13]. CMD is known to be 

associated with multiple autoimmune diseases, as well as 

some alterations in the immune system [11-13]. ARVCF also 

is related to the protein p120 subfamily of armadillo-related 

proteins, which includes p0071 and delta-catenin/NPRAP; 

these are distantly related plakophilins, and are involved in 

cell-cell adhesion [11-13]. In our current study, we investi-

gated whether ARVCF was expressed in the skin, including 

the sebaceous glands and their neurovascular supply struc-



Research  |  Dermatol Pract Concept 2017;7(4):2 5

IIF: Performed as the DIF, but utilizing skin from plastic 

surgeries as an antigen source.

Colocalization of the patient’s autoantibodies with com-

mercial antibodies utilizing confocal microscopy (CFM): Our 

CFM studies were performed as previously described [8,9]. 

In brief, we utilized standard 20X and 40X objective lenses; 

each photoframe included an area of approximately 440 x 

330 μm. Images were obtained using EZ-1 image analysis 

software (Nikon, Tokyo, Japan). For colocalization experi-

ments with serum autoantibodies, we used the previously 

described antibodies to ARVCF.

Indirect immunoelectron microscopy (IEM): Our tech-

nique was performed as described [8,9]. In brief, postembed-

ding immunogold labeling was performed on samples on the 

subjects of the study. Mouse skin was used as an antigen; the 

tissue was fixed in 4% glutaraldehyde with 0.2% parafor-

maldehyde, and embedded in Lowicryl® resin [8,9]. The tissue 

was then sectioned at a 70 nm thickness. The samples were 

blocked with a solution from Aurion™ (Electron Microcopy 

Sciences/EMS; Hatfield, PA, USA). Grids were then washed 

with PBS-BSAC (Aurion™, EMS). The primary antibodies 

were incubated, washed, and a secondary antibody solution, 

specifically 10 nm Gold-conjugated protein A PBS-BSAC 

(Aurion, EMS™) was applied [8,9]. The samples were then 

double-stained with uranyl acetate and lead citrate. The 

samples were observed under a Hitachi H7500 transmission 

electron microscope. Immunogold particle images displaying 

any pattern of positivity were then converted to TIF format.

Immunoadsorption of skin Dsg1 1 autoantibodies: 

Patients with El Bagre-EPF have circulating autoantibod-

ies directed against Dsg1 [5,6]. Based on the fact that the 

purified tryptic fraction of Dsg1 induces loss of adhesion in 

organ culture and in a neonatal mouse model, it has been 

proposed that these anti-Dsg1 antibodies play a pathogenic 

role in blister formation. To investigate if the ARVCF putative 

autoantibodies reactivity was the same as shown by Dsg1, 

we performed immunoadsorption experiments as previously 

described by incubating the tryptic ectodomain of Dsg1 

with samples that tested positive for DIF and IIF [14]. We 

used affinity tryptic-purified antigen, obtained as described 

using the Con A column [14]. In brief, protein samples were 

released from bovine snout epidermis by means of trypsin 

digestion, and purified with the use of a Con A column. The 

eluted Dsg1 antigen was then incubated with El Bagre-EPF 

DIF and IIF slides that were positive previously in colocaliza-

tion of ARVCF with the El Bagre-EPF serum.

Statistical analysis: We used Fisher exact test to compare 

two nominal variables (e.g., positive and negative) of anti-

body response. P < 0.05 with a 95% of confidence or more 

was considered statistically significant. We used the software 

GraphPad QuickCalcs (GraphPad Sofware Inc., La Jolla, 

CA, USA).

Results

A clinical picture of an exfoliative lesion of El Bagre-EPF is 

shown in Figure 1a. In Figure 1b, we show the corresponding 

histologic pattern. Our testing demonstrated positive staining 

for ARVCF in all layers of the epidermis, on the basement 

membrane zone and in upper areas of the subjacent dermis 

(including cell junctions and neurovascular bundles) by DIF, 

IIF, CFM, IB, and IEM. See Figure 1c, demonstrating one 

example of DIF staining with colocalization of the El Bagre-

EPF autoantibodies and ARVCF.

Overall, 40/45 patients affected by El Bagre-EPF dem-

onstrated autoantibodies that colocalized perfectly with 

the ARVCF antibody via DIF. In the remaining five patients 

affected by El Bagre-EPF we observed the expression of 

ARVCF, but the autoantibodies did not colocalize with the 

ARVCF antibody. In Table 1 are shown the results of the 

polyclonal immune response using DIF and IIF, the strength 

of the stains and the colocalization with the El Bagre-EPF 

autoantibodies and the ARVCF reactivity.

The CFM studies also demonstrated 100% colocalization 

of the patient autoantibodies and the commercial antibody 

to ARVCF (p < 0.01) (Figure 1c, d). None of the controls 

from the endemic area showed autoantibodies colocalizing 

to ARVCF via DIF, IIF, CMF, or IEM. However, the ARVCF 

molecule is ubiquitous in the skin.

After the immunoadsorption with the pre-incubated 

Dsg1 antigen with the patient samples testing positive for 

colocalization with ARVCF, the immunoreactivity to ARCVF 

persisted.

Our IEM data (Figure 1e, f) demonstrated positive stain-

ing for patient autoantibodies in skin cell junctions. The IB 

studies confirmed multiple antigens detected by patient sera, 

that also perfectly colocalized with the Progen antibody to 

ARVCF (data not shown).

Discussion

To our knowledge, we present evidence for the first time in 

the medical literature that ARVCF is expressed in the skin 

via diverse methods. We also demonstrated that El Bagre-EPF 

autoantibodies colocalized with the commercial antibody 

to ARVCF from Progen in the skin of 40/45 patients. We 

further demonstrated that after immunoadsorption with an 

ectodomain of Dsg1 the reactivity remained, demonstrating 

that the El Bagre-EPF patient’s autoantibodies are directed to 

a non-Dsg1 antigen.

We noted that 5/45 El Bagre-EPF patients did not display 

autoantibodies against ARVCF. El Bagre EPF patients pres-

ent a diverse spectrum of clinical lesions (hyperpigmented, 

prurigoid, generalized, blistering, etc.) [1,3,5]. The patients 

may also present in an acute, relapsing or chronic stage of 

https://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=2&cad=rja&uact=8&ved=0ahUKEwjkxrSelOXSAhUFSCYKHYPMDSMQFgg4MAE&url=http%3A%2F%2Fgraphpad.com%2Fquickcalcs%2Fcontingency1%2F&usg=AFQjCNFmcQtFUoz8qKLz92JezpJ4WqbViQ
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6 Research  |  Dermatol Pract Concept 2017;7(4):2

metals and other metalloids [5] that can compete with cal-

cium. El Bagre soils are extremely acidic, contain very scarce 

organic matter and are thus scarce in calcium, phosphates, 

magnesium (Mg++), and potassium. Phosphates are constitu-

ents of ATP, DNA, RNA, and the phospholipids, which form 

all cell membranes where the cells junctions are situated. The 

existence or absence of a given metal/metalloid is crucial 

to the conformation or activity of most proteins. Thus, the 

metal/metalloid ions in the environment could compete with 

physiologic ions (e.g., Ca++), altering the conformation of 

relevant molecules and generating antigenicity.

ARVCF (A.K.A. catenin delta 1) binds sulfate (S04) as 

well as magnesium (Mg++ are their ligands. DP also has an 

S04 ligand and to phosphoserine is classified as UniProtKB/

disease. Thus, each case may present a range of autoantigens 

and immune responses, depending of the clinical phase of 

the disease. We also showed that the immune response is 

polyclonal in patients affected by El Bagre-EPF, as previously 

described [8,9].

We speculate that disruption of epidermal cells in El 

Bagre-EPF could induce epitope spreading, or expose new 

molecules that could then become antigenic since like Dsg1, 

ARVCF represents a cell junction protein. ARVCF is a protein 

with three cellular locations: in the plasma membrane, the 

cytoplasm and the nucleus [13-16].

We also hypothesize that ARVC becomes antigenic 

because this molecule is calcium (Ca++) dependent (similar to 

DSg1); further, that the El Bagre soils are polluted by mercury, 

Figure 1. (a) An El Bagre EPF clinical blis-

ter (black arrow). (b) H&E staining of one 

of multiple patterns seen in El Bagre EPF. 

In this case, note the loss of the upper lay-

ers of the epidermis (black arrow), and a 

dilated dermal blood vessel (blue arrow) 

with dermal edema and inflammation. (c) 

DIF of the skin from a patient affected by 

El Bagre-EPF, showing positive double stain-

ing in the epidermis (in orange stain, as re-

sult of the patient’s autoantibodies in green 

and the ARVCF in red) (+++) (black arrow), 

basement membrane zone (greenish stain) 

(+++) (white arrow) and a dermal neurovas-

cular bundle (yellowish stain) (+++) (blue 

arrow) using FITC conjugated anti-human 

IgG (green staining) and Alexa 555 con-

jugated ARVCF (red staining). The stain-

ing observed represents overlap staining of 

different strength from yellowish-orange 

to green (400X). (d) Confocal microscopy, 

with multiple channels of fluorescence uti-

lized. In the presented case we used a FITC 

channel (green peaks) (Excitation/Emission 

(nm):495/519), a DAPI channel (blue peaks) 

(Excitation/Emission (nm):360⁄460), and an 

Alexa Fluor®555 channel (red peaks) (Exci-

tation /Emission (nm):555/568). The graphic 

shows the colocalization of the peaks of the 

immunofluorescence of the patient’s anti-

bodies (green peaks; white arrow) with the 

ARVCF antibody (red peaks; white arrow). 

Both green and red are aligned, demonstrat-

ing colocalization. The blue peaks represent 

DAPI (nuclear counterstaining). (e) and (f) 

IEM photographs of patient skin, show-

ing ARVCF antibodies labelled with 10 nm 

Gold-conjugated protein A antibodies (tiny 

black dots). In (e), the antibodies are located 

in the epidermal cells junctions (black arrow), at the cutaneous basement membrane zone (black dots; red arrow) and in the upper papillary 

dermis (tiny black dots; blue arrow) (100kV). (f) Positive IEM staining in the upper epidermal keratinocytes cells junction showing ARVCF 

antibody gold labeled grouped in some areas (tiny black dots; red arrows) (100kV). [Copyright: ©2017 Abreu Velez et al.]



Research  |  Dermatol Pract Concept 2017;7(4):2 7

respective sequence is available to researchers to investigate 

if ARVCF may be a putative antigen in other autoimmune 

blistering diseases. More than 9% of the protein sequences 

provided by UniProtKB are derived from translation of the 

coding sequences.

Acknowledgement

We wish to thank Jonathan S. Jones, HT (ASCP) at Georgia 

Dermatopathology Associates for excellent technical assis-

tance.

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Swiss-Prot (O00192), and is a member of the catenin family, 

which contain an armadillo/beta-catenin-like repeat sequence 

[11-13]. ARVCF is a Ca++ dependent cell-cell adhesion mol-

ecule, acting via plasma membranes. The catenin family plays 

an important role in the formation of adherens junction 

complexes, which are thought to facilitate communication 

between the inner and outer environments of cells [11-13]. 

The data suggest that ARVCF is a putative El Bagre-EPF anti-

gen. Our data indicates that ARVCF is a putative non-Dsg1 

antigen in El Bagre-EPF patients.

The p120 protein family includes p120-catenin, δ-catenin, 
p0071, and ARVCF [10]. ARVCF associates with p68, hnRNP 

H2, SFF1, zonula occludens ZO-1 and ZO-2 (in the last two, 

binding to PDZ-domain proteins) [11-13].

All three diseases belonging to the CMD syndrome are 

associated with impaired function of T cells due to abnormal 

development of the thymus gland, abnormalities of T-cell 

clonality, and/or in B lymphocytic function [11-13,16]. We 

believe there is an abnormality in the immune response in 

El Bagre-EPF patients, which we are currently investigating.

Pemphigus Abreu-Manu differs from previously described 

forms of EPF. Indeed, El Bagre-EPF is a chronic inflammatory 

disease that has protean manifestations, including a form 

fruste (localized to the skin and resembling Senear-Usher 

syndrome, and with a unique autoimmune response due to 

environmental and genetic factors) with photosensitivity; and 

a systemic form [8,9]. Patients affected by this disease may 

present with relapsing episodes; the systemic form affects 

multiple organs with a less favorable prognosis [5,6,12].

In conclusion, we demonstrate the expression of the pro-

tein ARCVF in multiple areas of the skin. We prove colocal-

izing or this protein with the majority of the El-Bagre-EPF 

autoantibodies, and that the reactivity is directed against a 

non-Dsg1 antigen. We aim in our future research to establish 

the precise pathologic role of ARVCF in El Bagre-EPF patients 

and in the skin. The ARVCF UniProtKB/Swiss-Prot (000192) 

TABLE 1. DIF and IIF autoantibody staining in the skin and colocalization with ARVCF

DIF IIF

El Bagre-EPF 
autoantibodies 

Number of 
positive cases

Strength of 
staining

Colocalization 
with ARVCF

Number of 
positive cases

Strength of 
staining

Colocalization 
with ARVCF

IgG 40/45 (+++) 100% 39/45 (+++) 100%

Fibrinogen 39/45 (+++) 100% 38/45 (++) 100%

IgM 38/45 (+++) 100% 38/45 (+++) 100%

Albumin 38/45 (+++) 100% 38/45 (++) 100%

Complement/C3c 35/45 (+++) 100% 35/45 (++) 100%

Complement/C1q 35/45 (++) 100% 35/45 (++) 100%

IgA 15/45 (++) 100% 15/45 (++) 100%

IgD 16/45 (++) 100% 16/45 (++) 100%

IgE  7/45 (++) 100%  7/45 (++) 100%



8 Research  |  Dermatol Pract Concept 2017;7(4):2

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