The Comprehensive Genetic Test for Progeria and Progeroid Syndromes utilizes next-generation sequencing (NGS) to examine 17 genes associated with premature aging syndromes, DNA repair defects, and metabolic or nuclear envelope disorders. It is a targeted gene panel specifically designed to support accurate diagnosis, risk assessment, and prevention.
More Information
The Progeria and Progeroid Syndromes Panel is a high-precision genetic test designed to identify pathogenic variants associated with Hutchinson-Gilford Progeria Syndrome (HGPS) and a broader group of progeroid syndromes. These rare genetic disorders mimic accelerated aging. In the context of functional medicine, this panel provides deep insight into the molecular disruptions affecting nuclear architecture, DNA repair, chromatin remodeling, and cellular senescence. By analyzing key genes involved in nuclear lamina stability and genomic maintenance, the test helps elucidate the root causes of syndromes characterized by premature aging, growth retardation, and multisystem degeneration.
Progeroid syndromes represent a heterogeneous set of disorders that share clinical features of early-onset aging, including loss of subcutaneous fat, skin thinning, hair loss, joint stiffness, osteoporosis, and cardiovascular complications. The most studied and prototypical form is Hutchinson-Gilford Progeria Syndrome, caused by mutations in the LMNA gene, which encodes lamin A/C. These proteins are critical for the structural support and function of the nuclear envelope. A defective splice variant, progerin, leads to abnormal nuclear morphology, genomic instability, and increased cellular apoptosis. The accumulation of progerin disrupts stem cell homeostasis and impairs tissue regeneration, contributing to the systemic decline observed in affected individuals.
Beyond LMNA, mutations in genes such as ZMPSTE24, BANF1, WRN, POLD1, RECQL4, and ERCC5 are also implicated in other progeroid conditions, including mandibuloacral dysplasia, Werner syndrome, Rothmund-Thomson syndrome, and xeroderma pigmentosum group G. These genes are responsible for post-translational processing of nuclear proteins, DNA helicase function, polymerase proofreading, and nucleotide excision repair. Their dysfunction leads to increased accumulation of DNA damage, impaired chromosomal stability, and heightened sensitivity to oxidative stress, all of which are closely linked to aging and degenerative diseases. When the integrity of these mechanisms is compromised, accelerated cellular senescence and early organ deterioration may result.
The genes analyzed in the Progeria and Progeroid Syndromes Panel govern essential pathways for genomic fidelity, nuclear structure, and tissue renewal. Loss-of-function mutations or structural anomalies in these genes cause a systemic imbalance between cellular aging and repair mechanisms. This test is instrumental in uncovering inherited causes of complex, early-onset degenerative symptoms with no clear metabolic or environmental origin. It can provide diagnostic clarity in cases of growth failure, skin and bone changes, or unexplained cardiovascular deterioration in childhood. By identifying the precise genetic basis of progeroid syndromes, the test enables targeted clinical monitoring and supports strategies to mitigate the effects of premature biological aging.
The test is performed in a clinical laboratory accredited to ISO 15189 and certified by CLIA and CAP, ensuring the validity, accuracy and international recognition of the results.
