Piebaldism and chromatophore development in reptiles are linked to the tfec gene

Reptiles display great diversity in color and pattern, yet much of what we know about vertebrate coloration comes from classic model species such as the mouse and zebrafish.1,2,3,4 Captive-bred ball pythons (Python regius) exhibit a remarkable degree of color and pattern variation. Despite the wide range of Mendelian color phenotypes available in the pet trade, ball pythons remain an overlooked species in pigmentation research. Here, we investigate the genetic basis of the recessive piebald phenotype, a pattern defect characterized by patches of unpigmented skin (leucoderma). We performed whole-genome sequencing and used a case-control approach to discover a nonsense mutation in the gene encoding the transcription factor tfec, implicating this gene in the leucodermic patches in ball pythons. We functionally validated tfec in a lizard model (Anolis sagrei) using the gene editing CRISPR/Cas9 system and TEM imaging of skin. Our findings show that reading frame mutations in tfec affect coloration and lead to a loss of iridophores in Anolis, indicating that tfec is required for chromatophore development. This study highlights the value of captive-bred ball pythons as a model species for accelerating discoveries on the genetic basis of vertebrate coloration.

Observations of hypomelanosis in the nurse shark Ginglymostoma cirratum

Hypomelanosis refers to a suite of skin pigment abnormalities, including albinism, leucism and piebaldism. While documented across many vertebrate species, examples of hypomelanosis are rarely seen in chondrichthyans, with little insight into the potential effects on survival. Here, we report the first observation of abnormal skin pigmentation indicative of piebaldism in the Atlantic nurse shark Ginglymostoma cirratum, representing only the second reported case of skin aberrations for this species. This extremely rare observation is discussed in the broader context of fitness variation and long-term survival.

Neonatal Onset of Hemophagocytic Lymphohistiocytosis Due to Prenatal Varicella-Zoster Infection in a Neonate with Griscelli Syndrome Type 2

Type 2 Griscelli syndrome (Type2 GS) is a primary inborn error of the immune system, classified in the immune dysregulation group.1,2 There are three different types of the disease, with different genetic causes responsible for the autosomal recessive inheritance pattern. Although hypopigmentation is common in all variants, neurological involvement or immunodeficiency with varying severity is seen in different types. Molecular motor protein myosin 5 an (MYo5A) [Type1GS], guanosine Triphosphate (GTP) binding protein (RAB27A) [Type2GS], and mutation in human melanophilin (MLPH) [Type 3GS] which is limited to hypopigmentation are reported as the known genetic defects in GS.3 Severe, ineffective, and uncontrolled inflammatory reactions are referred to as the pathogenesis of Hemophagocytic lymphohistiocytosis (HLH). HLH is a life-threatening condition that can be defined as either primary or secondary. Secondary causes happen in the context of autoimmunity, malignancy, spontaneous, or infections.4 Prenatal infections play an important role in causing long-term complications in the fetus. Some of them include toxoplasmosis, rubella, cytomegalovirus, herpes simplex, and other organisms including syphilis, parvovirus, and Varicella zoster, known as TORCH syndrome (5).TORCH has been well described for a long time but there are limited reports of developing HLH in the context of prenatal infections. We described a type 2GS syndrome with neonatal-onset HLH triggered by a prenatal infection.

Development, characterization, and hematopoietic differentiation of Griscelli syndrome type 2 induced pluripotent stem cells

BACKGROUND

Griscelli syndrome type 2 (GS-2) is a rare, autosomal recessive immune deficiency syndrome caused by a mutation in the RAB27A gene, which results in the absence of a protein involved in vesicle trafficking and consequent loss of function of in particular cytotoxic T and NK cells. Induced pluripotent stem cells (iPSC) express genes associated with pluripotency, have the capacity for infinite expansion, and can differentiate into cells from all three germ layers. They can be induced using integrative or non-integrative systems for transfer of the Oct4, Sox2, Klf4, and cMyc (OSKM) transcription factors. To better understand the pathophysiology of GS-2 and to test novel treatment options, there is a need for an in vitro model of GS-2.

METHODS

Here, we generated iPSCs from 3 different GS-2 patients using lentiviral vectors. The iPSCs were characterized using flow cytometry and RT-PCR and tested for the expression of pluripotency markers. In vivo differentiation to cells from all three germlines was tested using a teratoma assay. In vitro differentiation of GS-2 iPSCs into hematopoietic stem and progenitor cells was done using Op9 feeder layers and specified media.

RESULTS

All GS-2 iPSC clones displayed a normal karyotype (46XX or 46XY) and were shown to express the same RAB27A gene mutation that was present in the original somatic donor cells. GS-2 iPSCs expressed SSEA1, SSEA4, TRA-1-60, TRA-1-81, and OCT4 proteins, and SOX2, NANOG, and OCT4 expression were confirmed by RT-PCR. Differentiation capacity into cells from all three germ layers was confirmed using the teratoma assay. GS-2 iPSCs showed the capacity to differentiate into cells of the hematopoietic lineage.

CONCLUSIONS

Using the lentiviral transfer of OSKM, we were able to generate different iPSC clones from 3 GS-2 patients. These cells can be used in future studies for the development of novel treatment options and to study the pathophysiology of GS-2 disease.

Another case of preaxial polydactyly and white forelock in branchio-oculo-facial syndrome

A 1-year-old male with branchio-oculo-facial syndrome together with preaxial polydatyly and a white forelock at birth is described. This is only the second case where preaxial polydactyly has been described in branchio-oculo-facial syndrome. In both cases a diagnosis of Waardenburg syndrome had been considered.

Impaired growth and differentiation of diploid but not immortal melanoblasts from endothelin receptor B mutant (piebald) mice

Endothelin 3 (Edn3) and its preferred receptor, endothelin receptor B (Ednrb), are implicated in development, especially that of two neural-crest-derived cell lineages: melanocytes and enteric ganglion cells. Mice and humans with a null mutation at either locus can show major deficiencies in both cell types: congenital white spotting and aganglionic megacolon (Hirschsprung disease in human). Numbers of early (migrating) embryonic melanoblasts are low in Ednrb(ls) mutant mice, while added Edn3 appears to promote the growth of melanocyte precursors in neural crest cultures. However, it is hard to assess cell differentiation in these mixed cultures, and it is not known whether Ednrb has any role in the postnatal melanocytic lineage. We have therefore studied primary cultures of neonatal melanoblasts homozygous for the piebald (Ednrb(s)) mutation. These mutant melanoblasts showed severe impairment of both net cell growth and differentiation compared to wild-type melanoblasts. They were also unresponsive to stimulation of growth by cholera toxin. We have established three immortal lines of melanoblasts and one of melanocytes homozygous for Ednrb(s). These immortal lines, however, had no detectable deficiency of growth or differentiation as judged by cell counts, induced pigmentation and immunocytochemistry for melanocytic markers. Consistent with this, neither Ednrb nor Edn3 mRNA was detected in 3/3 tested immortal lines of mouse melanoblasts and 5/5 lines of melanocytes, of various genotypes. We also report for the first time a method to grow immortal melanoblasts in pure culture, without feeder cells.

White mutants in mice shedding light on humans

In this article we describe the rapid advances made in the molecular genetics of three inherited pigmentation disorders: albinism, piebaldism, and vitiligo, all of which throw light on normal pigment cell function. The focus is on studies in mice, with comparison of data in humans. The critical role of tyrosinase (c-locus or human tyrosinase protein) in normal pigmentation and albinism has been reinforced by the cloning and identification of mutations in tyrosinase and two other melanocyte-specific oxidoreductases structurally related to but functionally different from tyrosinase: the (b) brown-locus protein/gp75/catalase B and dopachrome tautomerase. Each possesses a distinct enzyme activity and yet the three share homology in strategic regions. Most of the point mutations that reduce or abrogate the respective enzyme activities are located in those regions. Tyrosinase-negative albinism is caused only by defects in tyrosinase. A locus for human tyrosinase-positive albinism has been recently mapped to chromosome 15q11.2-->q12, at a gene identified in mice as pink-eyed dilution. On the other hand, several genes encoding proteins critical for the proliferation of melanocytes are known to control the piebald phenotype. So far identified are two membrane-receptor tyrosine kinases, c-Kit and PDGF-R/alpha, and the ligand for c-kit, MGF (mast-cell growth factor, also known as stem-cell factor, c-Kit-ligand, or steel factor). Mutations in W/c-kit (white spotting), Ph/Pdgfr/a (patch), and Sl/MGF (steel), lead to a reduction in receptor kinase activity and failure of melanocytes to thrive and reach the skin during embryogenesis. Finally, mouse mutant models suggest at least two possible causes for vitiligo, a progressive loss of pigmentation that occurs after birth. In one mutant, the Blt (light) mouse, the cyclic death of hair melanocytes may be due to the toxicity of intermediates and byproducts of melanogenesis in the presence of a dysfunctional b-locus protein. In the other model, the "vitiligo mouse," in which the allele vit has been assigned to the microphthalmia (mi) locus, the loss of melanocytes may be caused by defective signal transduction, because in addition to vitiligo mivit/mivit mice have extensive piebaldism.

Albinism, partial albinism, and vitiligo

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