Recurrent p.H119Y variant in MAP2K1 expands the phenotypic spectrum of MAP2K1-related RASopathy.

We report three unrelated individuals with atypical clinical findings for cardio-facio-cutaneous (CFC) syndrome, all of whom have the same novel, heterozygous de novo p.H119Y (c.355 C>T) transition variant in MAP2K1, identified by exome sequencing. MAP2K1 encodes MEK1, dual specificity mitogen-activated protein kinase kinase 1, and is one of four genes in the canonical RAS/MAPK signal transduction pathway associated with CFC syndrome. The p.H119Y variant is a non-conservative amino acid substitution that is predicted to impact the tertiary protein structure, and it occurs at a position in the protein kinase domain of MAP2K1 that is highly conserved across species. The clinical findings in these three individuals include facial features that are nonclassical for CFC syndrome, extremely poor weight gain, absence of congenital cardiac defects or cardiomyopathy, normal cognition or only mild intellectual disabilities, normal hair, mild skin abnormalities, and consistent behavioral features of anxiety, photophobia, and sensory hypersensitivities. These individuals expand the phenotypic spectrum of MAP2K1-related RASopathy.

Erratum. Atypical Diabetes: What Have We Learned and What Does the Future Hold? Diabetes Care 2024;47:770-781.

On p. 777 of the article cited above, it was incorrectly stated that patients with pancreatic diabetes may have elevated fecal elastase. The correct text is as follows: "In the case of pancreatic diabetes, patients may have low fecal elastase." The authors apologize for the error. The online version of the article (https://doi.org/10.2337/dci23-0038) has been revised.

Atypical Diabetes: What Have We Learned and What Does the Future Hold?

As our understanding of the pathophysiology of diabetes evolves, we increasingly recognize that many patients may have a form of diabetes that does not neatly fit with a diagnosis of either type 1 or type 2 diabetes. The discovery and description of these forms of "atypical diabetes" have led to major contributions to our collective understanding of the basic biology that drives insulin secretion, insulin resistance, and islet autoimmunity. These discoveries now pave the way to a better classification of diabetes based on distinct endotypes. In this review, we highlight the key biological and clinical insights that can be gained from studying known forms of atypical diabetes. Additionally, we provide a framework for identification of patients with atypical diabetes based on their clinical, metabolic, and molecular features. Helpful clinical and genetic resources for evaluating patients suspected of having atypical diabetes are provided. Therefore, appreciating the various endotypes associated with atypical diabetes will enhance diagnostic accuracy and facilitate targeted treatment decisions.