KCTD1/KCTD15 complexes control ectodermal and neural crest cell functions, and their impairment causes aplasia cutis
Jackelyn R. Raymundo, Hui Zhang, Giovanni Smaldone, Wenjuan Zhu, Kathleen E. Daly, Benjamin J. Glennon, Giovanni Pecoraro, Marco Salvatore, William A. Devine, Cecilia W. Lo, Luigi Vitagliano, Alexander G. Marneros
Jackelyn R. Raymundo, Hui Zhang, Giovanni Smaldone, Wenjuan Zhu, Kathleen E. Daly, Benjamin J. Glennon, Giovanni Pecoraro, Marco Salvatore, William A. Devine, Cecilia W. Lo, Luigi Vitagliano, Alexander G. Marneros
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Research Article Dermatology Development

KCTD1/KCTD15 complexes control ectodermal and neural crest cell functions, and their impairment causes aplasia cutis

Abstract

Aplasia cutis congenita (ACC) is a congenital epidermal defect of the midline scalp and has been proposed to be due to a primary keratinocyte abnormality. Why it forms mainly at this anatomic site has remained a long-standing enigma. KCTD1 mutations cause ACC, ectodermal abnormalities, and kidney fibrosis, whereas KCTD15 mutations cause ACC and cardiac outflow tract abnormalities. Here, we found that KCTD1 and KCTD15 can form multimeric complexes and can compensate for each other’s loss and that disease mutations are dominant negative, resulting in lack of KCTD1/KCTD15 function. We demonstrated that KCTD15 is critical for cardiac outflow tract development, whereas KCTD1 regulates distal nephron function. Combined inactivation of KCTD1/KCTD15 in keratinocytes resulted in abnormal skin appendages but not in ACC. Instead, KCTD1/KCTD15 inactivation in neural crest cells resulted in ACC linked to midline skull defects, demonstrating that ACC is not caused by a primary defect in keratinocytes but is a secondary consequence of impaired cranial neural crest cells, giving rise to midline cranial suture cells that express keratinocyte-promoting growth factors. Our findings explain the clinical observations in patients with KCTD1 versus KCTD15 mutations, establish KCTD1/KCTD15 complexes as critical regulators of ectodermal and neural crest cell functions, and define ACC as a neurocristopathy.

Authors

Jackelyn R. Raymundo, Hui Zhang, Giovanni Smaldone, Wenjuan Zhu, Kathleen E. Daly, Benjamin J. Glennon, Giovanni Pecoraro, Marco Salvatore, William A. Devine, Cecilia W. Lo, Luigi Vitagliano, Alexander G. Marneros

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Figure 4

Expression pattern of Kctd1 and Kctd15.

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Expression pattern of Kctd1 and Kctd15. (A) X-gal labeling of skin from ...
(A) X-gal labeling of skin from adult Kctd15LacZ/WT and Kctd1LacZ/WT mice shows that Kctd1 and Kctd15 are expressed in epidermis and hair follicles. Scale bars: 250 μm. (B) Kctd1 and Kctd15 are expressed in developing epidermis and whiskers (E14.5 Kctd15LacZ/WT and Kctd1LacZ/WT mice). Scale bars: top, 250 μm; bottom, 100 μm. (C) X-gal staining of E10.5 Kctd15LacZ/WT and Kctd1LacZ/WT embryos shows labeling pattern similar to that of neural crest reporter mice (16). (D) Kctd1 and Kctd15 expression in mouse NCC populations (total 5,741 cells; ref. 18). BCC, boundary cap cells; ChC, chromaffin cells; DRG, dorsal root ganglia; enFib, endoneural fibroblasts; Sat, satellite; SC, Schwann cells; Symp, sympathetic neurons. (E) KCTD1 and KCTD15 expression in primate NCC populations (total 56,636 cells; ref. 22). (F) Comparison of expression of Kctd1 and Kctd15 in both cardiac NCC–derived (CNCC) and non–cardiac NCC–derived (non-CNCC) cells in mice between E8.5 and E10.5 (total 4,651 cells, including 260 CNCC and 4,391 non-CNCC; ref. 17). (G) Kctd1 and Kctd15 expression in melanocytes of developing mouse skin at E13.5 based on scRNA-Seq data (143 melanocytes in data set; ref. 48). Adjusted P value and log2(fold change) Kctd15/Kctd1 are shown. Percentages indicate relative contribution to overall combined Kctd1 and Kctd15 transcript levels in these melanocytes. (H) Left: Wnt1Cre+Kctd15fl/fl mice develop a white belly patch due to lack of melanocytes. Right: Lack of Melan-A+ melanocytes in hair follicle whole mounts in white patches (yellow arrows), in contrast to presence of melanocytes in adjacent pigmented hair follicles (white arrows). Original magnification, ×20. (I) White belly patch size increases in this order: Wnt1Cre+Kctd1fl/flKctd15fl/WT mice < Wnt1Cre+Kctd15fl/fl mice < Wnt1Cre+Kctd1fl/WTKctd15fl/fl mice. Y axis, pixel area of white patches (normalized to length scale). Mean ± SEM; P < 0.0001 (1-way ANOVA with test for linear trend among these 3 groups). (J) siRNA-mediated knockdown of Kctd15 or Pax3 in mouse melanocytes (Melan-A cells) inhibits expression of Kctd15 (Kctd15 transcript levels normalized to 36b4 and to control group treated with scrambled siRNA). Results shown for 2 different primer pairs for Kctd15 and Pax3. N = 4 per group. Mean ± SEM; P values (Kruskal-Wallis test with Dunn’s multiple-comparison test).