Dermatology: Practical and Conceptual


Research  |  Dermatol Pract Concept 2018;8(1):1 1

DERMATOLOGY PRACTICAL & CONCEPTUAL
www.derm101.com

Patients affected by endemic pemphigus foliaceus 
in Colombia, South America exhibit autoantibodies 

to optic nerve sheath envelope cell junctions
Ana Maria Abreu-Velez1, Wendy Gao2, Michael S. Howard1

1 Georgia Dermatopathology Associates, Atlanta, GA, USA

2 Biotechnology, Charlotte, NC, USA

Key words: endemic pemphigus in El Bagre, optic nerve junction, optic cell junction, MYZAP, ARVCF, p0071, desmoplakins

Citation: Abreu-Velez AM, Gao W, Howard MS. Patients affected by endemic pemphigus foliaceus in Colombia, South America exhibit 
autoantibodies to optic nerve sheath envelope cell junctions. Dermatol Pract Concept. 2018;8(1):1-6. DOI: https://doi.org/10.5826/
dpc.0801a01

Received: September 20, 2017; Accepted: November 27, 2017; Published: January 31, 2018

Copyright: ©2018 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.

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. E-mail: abreuvelez@yahoo.com

Background: The majority of the patients affected by a new variant of endemic pemphigus foliaceus 
in El Bagre, Colombia (El Bagre EPF or pemphigus Abreu-Manu), have experienced vision problems; 
we have previously reported several ocular abnormalities.

Methods: Here, we aimed to investigate reactivity to optic nerves in these patients. We utilized bovine, 
rat and mouse optic nerves, and performed immunofluorescence and confocal microscopy to test for 
optical nerve autoreactivity. We tested 45 patients affected by this disease and 45 controls from the 
endemic area matched by age, sex and work activity.

Results: Overall, 37 of the 45 patient sera reacted to the optic nerve envelope that is composed of 
leptomeninges; the reactivity was polyclonal and present mostly at the cell junctions (P < 0.001). The 
immune response was directed against optic nerve sheath cell junctions and the vessels inside it, as 
well as other molecules inside the nerve. No control cases were positive. Of interest, all the patient 
autoantibodies co-localized with commercial antibodies to desmoplakins I–II, myocardium-enriched 
zonula occludens-1- associated protein (MYZAP), armadillo repeat gene deleted in velo-cardio-facial 
syndrome (ARVCF), and plakophilin-4 (p0071) from Progen Biotechnik (P < 0.001).

Conclusion: We conclude that the majority of the patients affected by pemphigus Abreu-Manu have 
autoantibodies to optic nerve sheath envelope cell junctions. These antibodies also co-localize with ar-
madillo repeat gene deleted in velo-cardio-facial syndrome, p0071 and desmoplakins I–II. The clinical 
significance of our findings remains unknown.

ABSTRACT

https://doi.org/10.5826/dpc.0801a01
https://doi.org/10.5826/dpc.0801a01


2 Research  |  Dermatol Pract Concept 2018;8(1):1

65146). We utilized antibodies to armadillo repeat gene 

deleted in velo-cardio-facial syndrome (ARVCF) (polyclonal 

antibody, source guinea pig, tested in human and bovine; 

Progen Biotechnik, cat no. GP155); for its secondary, we 

used Alexa Fluor- 555 goat-anti-guinea pig from Molecular 

Probes/ Life Technologies/Thermo Fisher Scientific (Waltham, 

MA, USA). We also utilized an antibody to plakophilin-4 

(p0071); Progen Biotechnik, cat no. 651166) and a mouse 

monoclonal antibody for myocardium-enriched zonula 

occludens-1- associated protein (MYZAP) [Progen Biotech-

nik, cat no. 651169]. As a secondary antibody for DP-I–II, 

the p0071 and the MYZAP, we utilized Texas red-conjugated 

goat anti-mouse IgG from Thermo Fisher. The samples were 

consistently run with positive and negative controls. We 

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

positive (++) and strongly positive (+++).

IIF

In brief, for IIF we incubated 4-micron thick optic nerve 

sections from animal sources (cow, rat and mouse) on glass 

microscopic slides with secondary antibodies as previously 

described, but with some modifications as follows [5–8]. The 

rest of the procedure was done as it was for DIF.

Confocal microscopy

Confocal microscopy was performed as previously described 

[12].

Statistical analysis

We used Fisher’s exact test to compare two nominal variables 

(e.g., positive and negative) of antibody response. We also 

compared the differences when evaluating: (i) positivity of the 

El Bagre EPF autoantibodies between patient cases and con-

trols and (ii) patient antibody results versus the commercial 

antibodies to MYZAP, p0071, DP-I–II and ARVCF. P < 0.01 

with a 98% of confidence or more was considered statistically 

significant. We used the software GraphPad QuickCalcs from 

GraphPad Software (La Jolla, CA, USA).

Results

Using IIF and CFM, 35 of the 45 patients affected by El Bagre 

EPF displayed autoantibodies to the optic nerve envelope (P 

< 0.001). The predominant autoantibodies were to IgG, IgM, 

complement/C1q, complement/C3, fibrinogen and albumin; 

in some cases, we also observed reactivity to IgA, IgD and IgE 

(see Table 1, that includes the daily dose of prednisone taken 

by each patient). As mentioned, the reactivity against the optic 

nerve sheath cells junctions and their vessels was polyclonal 

and distributed as follows: IgG (n = 37), IgM (28/45), albumin 

(n = 27), complement/C1q (n = 25), complement/C3c (n = 26), 

Introduction

Endemic pemphigus foliaceus (EPF) represents an autoim-

mune blistering disease presenting in an endemic fashion in 

South America, Central America, and Tunisia, Africa [1–4]. 

We have previously described a new variant of EPF in El 

Bagre, Colombia (El Bagre EPF, or pemphigus Abreu-Manu) 

[5–7] and also reported ocular problems in these patients 

including entropion and/or ectropion, trichiasis, blepharo-

phimosis, thinned eyebrows, refractory defects, Meibominitis, 

and corticonuclear cataracts, among others [8]. In the pre-

steroid era, patients affected by Brazilian fogo selvagem also 

presented with ocular problems [9]. Here, we aim to continue 

characterizing the El Bagre EPF autoimmune response by 

studying optic nerve reactivity in these patients.

Methods

We tested 30 patients affected by El Bagre EPF, and 30 con-

trols from the endemic area matched by age, sex and work 

activities. A human quality assurance review board approved 

the studies at the Hospital Nuestra Señora del Carmen in El 

Bagre. The participants signed informed consent forms, and 

the patients were evaluated clinically, by hematoxylin–eosin 

(H & E) histology, direct and indirect immunofluorescence 

(DIF and IIF), immunohistochemistry, confocal microscopy 

(CFM), enzyme linked immunoassay (ELISA), immunob-

lotting (IB), and immunoprecipitation (IP), as previously 

described [5–12]. Only patients who fulfilled the full diag-

nostic criteria for El Bagre EPF were included, as follows: 

(i) patients displayed clinical and epidemiological features 

described for this disease; (ii) patients lived in the endemic 

area; (iii) the patient serum displayed intercellular staining 

between epidermal keratinocytes using DIF, and to the base-

ment membrane zone of the skin by either DIF or IIF, using 

fluorescein isothiocyanate-conjugated monoclonal antibodies 

to human total immunoglobulin (IgG), or to IgG4, as previ-

ously described [5–12]; (iv) the patient serum was positive 

by IB for reactivity against desmoglein (Dsg)1, as well as for 

plakin molecules as previously described [6,7]; (v) the patient 

serum immunoprecipitated a concanavalin A affinity-purified 

antigen bovine tryptic 45-kDa fragment of desmoglein 1 

(Dsg1) [10]; and (vi) the patient serum yielded a positive 

result using an ELISA when screening for autoantibodies to 

pemphigus foliaceus antigens [12].

DIF

Our studies were performed as previously described [5–8]. 

The slides were counterstained with 4,6-diamidino-2-phenyl-

indole (Pierce, Rockford, IL, USA). We also used antibodies 

to desmoplakins (DP)-I–II (mouse monoclonal multi-epitope 

cocktail; Progen Biotechnik [Heidelberg, Germany], cat no. 



Research  |  Dermatol Pract Concept 2018;8(1):1 3

arachnoid mater) is normally loose near the eyeball, with a 

much larger subarachnoid space between the optic nerve 

and its sheath than elsewhere in its course, thus presenting a 

bulbous appearance just behind the eyeball [13]. Unlike the 

orbital part of the sheath, the optic nerve in the optic canal 

is firmly bound to the dura by numerous thick fibrous bands 

connecting the dura to the pia [13]. These bands not only 

firmly hold the optic nerve in position in this region, but also 

hold the dura and the optic nerve close to one another. In 

this region, the subarachnoid space is reduced to almost a 

capillary size, which is interrupted by these bands [13]. The 

arachnoid and pia mater together are sometimes termed the 

leptomeninges, literally “thin meninges”; these are the two 

innermost layers of tissue that cover the brain and spinal 

cord. The outer blood–cerebrospinal fluid barrier is formed 

by leptomeningeal cells of the arachnoid mater [14]. The 

structures forming this barrier are tight junctions [14, 15]. 

Leptomeninges have multiple functions and anatomical 

relationships. The outer parietal layer of the arachnoid is 

impermeable to cerebral spinal fluid due to tight intercel-

lular junctions; elsewhere, leptomeningeal cells form des-

mosomes and gap junctions [16]. In contrast to the tight 

junctions, specific gap junction cell proteins have also been 

identified (connexins 26 and 43) [13]. Leptomeningeal cells 

also form channels in the core and apical cap of arachnoid 

granulations for the drainage of cerebral spinal fluid into 

venous sinuses. In the spine, leptomeninges form highly per-

forated intermediate sheets of arachnoid mater and delicate 

ligaments that compartmentalize the subarachnoid space; 

specifically, dentate ligaments anchor subpial collagen to the 

dura mater and stabilize the spinal cord [12].

The deposits of patient autoantibodies and other inflam-

matory molecules in the optic nerve sheath envelope cell junc-

fibrinogen (n = 37), IgE (n = 10), IgA (n = 10) and IgD (n = 

10) (see Table 1). The patient auto autoantibodies against 

the optic nerve sheath cell junctions co-localized with com-

mercial antibodies to DP-I–II, p0071, MYZAP and ARVCF 

from Progen (P < 0.001) using IIF and CFM (see Figures 1, 

2). Of interest, the patients with higher autoantibody titers 

displayed more vision loss and symptoms including blurred, 

hazy, or “milky” vision, refractory defects and amblyopia (P 

< 0.001). In addition, external examination of the El Bagre-

EPF patients displayed entropion and/or ectropion, trichiasis, 

blepharophimosis, thinned eyebrows, meibominitis, partial 

obstruction of the Meibomian gland ducts, pinguecula, actinic 

conjunctivitis, tarsal muscle thickening, edema, and pterygia 

in higher frequencies relative to the controls (P < 0.001).

Discussion

We have previously described ocular clinical alterations 

in patients affected by El Bagre EPF [8] as well as against 

nerves and neural mechanoreceptors [8]. We also have 

previously observed a polyclonal immune response in the 

patients affected by El Bagre EPF because they are exposed 

to many xenobiotic agents, as well as other tropical diseases 

that are putative triggers for this disease. In addition, many 

patients have a therapeutically induced immunosuppression, 

taking oral prednisone (usually <30 mg daily) [5,6]. The 

length of the optic nerve varies widely even between the two 

eyes of the same person and is on average approximately 

35–55 mm from the eyeball to the chiasma (including the 

intraocular, intraorbital, intracanalicular, and intracranial 

parts) [13]. Each part can be further subdivided histologi-

cally into a fiber layer, a prelaminar region, and a lamina 

cribrosa region [13]. The optic nerve sheath (dura mater and 

TABLE 1. Positive staining ratio of patient autoantibodies (Ab) to optic nerve envelope/sheath cell 
junctions using IIF and CFM with daily doses of prednisone and staining strengths. “Daily dosage of 

oral prednisone” and “strength of staining” were given with the average of 45 cases.

Percentage of Patients 
with Ab Positive 

Daily Dosage of Oral 
Prednisone

Number of Positive Cases Strength of Staining

IgG 10 mg 37/45 (++++)

Fibrinogen 15 mg 37/45 (++++)

Albumin 20 mg 27/45 (+++)

IgM 25 mg 28/45 (+++)

Complement/C3c 30 mg 26/45 (+++)

Complement/C1q 30 mg 25/45 (++)

IgA 30 mg 10/45 (++)

IgD 15 mg 10/45 (++)

IgE 20 mg 10/45 (+)

Kappa 15 mg 36/45 (+++)

Lambda 15 mg 36/45 (+++)



4 Research  |  Dermatol Pract Concept 2018;8(1):1

Figure 1. (a) Confocal microscopy using rat optic nerve as an antigen, and showing positive staining with desmoplakin (DP)-I–II (red stain-

ing) (+++) around the entire optic nerve envelope (white arrows), as well as inside the nerve (yellow arrows). Note correlating in the panels 

that the red staining co-localizes with patient autoantibodies labeled with fluorescein isothiocyanate (FITC)-conjugated antihuman immuno-

globulin (Ig)G (green staining) (+++) (original magnification 91000). The nuclei of the cells are counterstained in blue with 4,6-diamidino-

2-phenylindole dihydrochloride (DAPI) (+++). Confocal microscopy uses multiple channels of fluorescence. In the presented case, we used 

a FITC channel (green peaks) (excitation/emission, 495/519 nm), a DAPI channel (blue peaks) (excitation/emission, 360⁄460 nm), and an 

Alexa Fluor- 555 channel (red peaks) (excitation/emission, 555/568 nm). The lower right panel shows the co-localization of the peaks of the 

immunofluorescence of the patient’s antibodies (green peaks; white arrows) (+++) with the DP-I–II antibody (red peaks, white arrow) (+++). 

Both green and red are aligned, demonstrating co-localization. The blue peaks represent our DAPI nuclear counterstaining (+++). Note that 

yellow peaks are seen because they are showing the overlapping of red and excitation/emission peaks. (b, c) Staining of armadillo repeat gene 

deleted in velo-cardio-facial syndrome (ARVCF) (red staining, white arrow) (+++) (9200). In (c), note some type of neural receptor (showing 

the co-localization of both antibodies; white arrow) (+++). (d) IIF. The optic nerve envelope shows positivity with patient autoantibodies 

(green staining) labeled with FITC-conjugated antihuman IgG (1000X) (+++). Note also the yellow dot positive (a combination of red and 

(Continued next page)



Research  |  Dermatol Pract Concept 2018;8(1):1 5

ARVCF is part of the optic nerve, and co-localizes with auto-

antibodies from patients affected by pemphigus Abreu-Manu.

Armadillo repeat gene deleted in velo-cardio-facial syn-

drome (also termed Di George syndrome or 22q11.2 deletion 

syndrome) is a member of the catenin family [18]. The catenin 

family plays an important role in the formation of adherens 

junction (AJ) complexes, which are thought to facilitate com-

munication between the inside and outside environments 

of cells. The ARVCF gene was isolated in the search for 

the genetic defect responsible for the autosomal dominant 

tions likely promote inflammation, and may cause alterations 

in the shape of the optic nerve including tortuosity. These 

deposits also could cause edema, which can extend to the 

meningothelial cells (MECs), the lamina cribrosa and the 

adjacent extracellular matrix. These changes can, in turn, 

cause visual anomalies found in these patients. We have 

already described external anomalies in the eyes of the El 

Bagre-EPF patients [8].

We, and others, have previously shown that DP-I–II are 

part of the optic nerve sheet [8, 17]. Here, we show that 

Figure 2. (a) Indirect immunofluores-

cence (IIF) showing positive staining using 

patient autoantibodies labeled with FITC-

conjugated immunoglobulin (Ig)G (green 

staining) (+++) and armadillo repeat gene 

deleted in velo-cardio-facial syndrome 

(ARVCF) (red staining) (+++) in a folded 

optic nerve sheath. Note the orange stain-

ing (white arrows) as result of co-localiza-

tion of the green and red staining (origi-

nal magnification 9100). The nuclei of the 

cells are counterstained in blue with DAPI 

(+++). (b) Same as (a), but using FITC IgG 

(green, excitation/emission, 495/519 nm) 

(+++) alone. Note that ARVCF is shown 

in yellowish-orange (white arrows). (c) 

IIF showing optic nerve sheath detached 

from the optic nerve and showing positive 

staining with FITC-conjugated antihu-

man fibrinogen-labeled patient antibod-

ies (green staining) (++++) co-localizing 

with MYZAP (orange dots) (++) (white 

arrow) (9100). (d) IIF showing positive 

staining for FITC-conjugated antihuman 

complement/ C1q-labeled patient anti-

bodies (green staining) (+++) co-localizing 

with ARCVF in the optic nerve sheath 

(orange staining, red arrow) (++) as well 

as in some areas inside the nerve (white 

arrow) (9100). (e) IIF showing positive 

staining in the optic nerve sheath using 

FITC-conjugated antihuman IgD-labeled 

patient antibodies (green staining) (+++) 

and desmoplakins I and II (red staining) 

(+++); the combined staining appears or-

ange, white arrows) (9100). (f) Same than 

(e) but performed with FITC-conjugated 

IgD alone (green staining, white arrows) 

(+++). [Copyright: ©2018 Abreu-Velez et 

al.]

green) staining in the nerve sheath for p0071 (black arrows) (++). Note also that some parts of the optic nerve are 

also positive for p0071 (dots stains, red arrows) (++). The cell nuclei are counterstained in blue with DAPI. (e) A negative control, with nuclei 

counterstained in blue with DAPI (+++). [Copyright: ©2018 Abreu-Velez et al.]

Figure 1. (continued)



6 Research  |  Dermatol Pract Concept 2018;8(1):1

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velo-cardio-facial syndrome. The syndrome is a spectrum 

disorder; features and severity may vary greatly among 

affected people. Syndromic defects have been noted in the 

development of the parathyroid glands; “partial” defects with 

impaired thymic development, and susceptibility to autoim-

mune disease including pernicious anemia, psoriatic arthritis, 

Raynaud’s phenomenon, myasthenia gravis, warm antibody 

autoimmune polyendocrine syndrome type 1, rheumatoid 

arthritis, hemolytic anemia, autoimmune thrombocytopenic 

purpura, hypoparathyroidism and Hashimoto’s thyroiditis, 

among others (http://www.genecards.org/cgi-bin/carddisp.

pl?gene=ARVCF; accessed September 2017) [18]. Based on 

our data, we suggest that El Bagre EPF may also be associ-

ated with ARVCF and, further, that ARVCF may be part of 

a “predisposing condition for autoimmunity” in patients 

affected by El Bagre EPF, including the optic nerve envelope 

[18]. MYZAP represents a component of the cytoplasmic 

plaques of AJ; AJ connect the endothelial cells of mammalian 

lymphoid system with desmoplakins-containing complexus 

adhaerentes of the virgultar cells of lymph node sinuses 

[19]. MYZAP co-localizes with several cytoplasmic plaque 

proteins and with AJ-specific transmembrane molecules, 

including VE-cadherin [19]. Biochemical analyses, includ-

ing immunoprecipitation, have shown that N-cadherin, DP, 

desmoglein 2, plakophilin-2, plakoglobin and plectin are very 

sturdily bound AJ complex partners [19]. These facts support 

our data findings that MYZAP co-localized with DP-I–II and 

the El Bagre EPF autoantibodies in the cell junctions of the 

optic nerve sheath. In regard to the observed antibody co-

localization with p0071, MYZAP and DP-I–II and ARVCF, 

we note that all these molecules are cell junctions; we previ-

ously have shown that they co-localized with El Bagre EPF 

autoantibodies. Our findings may be indicative that they are 

indeed El Bagre EPF autoantigens [12]. Further research is 

needed to confirm this possibility.

Conclusion

Patients affected by El Bagre endemic pemphigus foliaceus 

exhibit autoantibodies to optic nerve sheath envelope cell 

junctions, and these seem to alter vision in the patients.

Acknowledgments: This study was funded by the Embassy 

of Japan in Bogota, Colombia; Alcaldia de El Bagre, Antio-

quia, Colombia, Sur America; Hospital Nuestra Señora del 

Carmen, El Bagre, Antioquia, Colombia; and Mineros SA El 

Bagre, Antioquia, Colombia.

References

 1. Abreu-Velez AM, Messias-Reason LJ, Howard MS, Roselino AM. 

Endemic pemphigus foliaceus over a century: part 1. North Am J 

Med Sci. 2010;2 (2): 51–59.