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Progerin

Progerin is an aberrant, permanently farnesylated isoform of the protein lamin A, generated through of prelamin A transcripts due to a heterozygous (c.1824C>T; p.Gly608Gly) in the LMNA gene. This mutation activates a cryptic splice donor site in exon 11, resulting in the deletion of 50 near the of the protein and the loss of the metalloprotease cleavage site required for normal lamin A maturation. As a result, progerin retains a hydrophobic farnesyl group, leading to its persistent association with the nuclear membrane and disruption of nuclear architecture. In individuals with Hutchinson-Gilford syndrome (HGPS), a rare autosomal dominant , progerin accumulation causes profound nuclear lobulation, blebbing, and dysfunction in vascular cells and other tissues, manifesting as accelerated aging phenotypes including loss of subcutaneous fat, alopecia, scleroderma-like skin changes, and severe . Affected children typically appear normal at birth but develop symptoms by age 2, with an average lifespan of 14.5 years, primarily due to or from progressive . Progerin impairs DNA double-strand break repair—HGPS fibroblasts exhibit 2.6 times more unrepaired breaks one week after exposure compared to controls—contributing to genomic instability and premature . Beyond HGPS, progerin is produced at low levels in normal human cells and tissues through physiologic activation of the same cryptic splice site in the LMNA gene, with expression increasing during replicative and organismal aging. This accumulation correlates with shortening and synergizes with dysfunction to induce markers, such as elevated SA-β-gal activity, in cultured fibroblasts, suggesting progerin may contribute to age-related nuclear defects and tissue decline in the general population. Current therapeutic strategies, including farnesyltransferase inhibitors like (Zokinvy™), reduce progerin and nuclear abnormalities, extending survival in HGPS patients by approximately 2.5 years, while emerging approaches target progerin production at the genetic or transcriptional level.

Molecular Biology

Genetic Origin

The LMNA gene, located on the long arm of chromosome 1 at position 1q22, encodes prelamin A, the precursor to mature lamin A, a key intermediate filament protein that forms the nuclear lamina underlying the inner nuclear membrane. Progerin is produced due to a recurrent point mutation in exon 11 of the LMNA gene, specifically c.1824C>T, which results in a silent substitution of glycine for glycine at codon 608 (p.Gly608Gly, also denoted G608G). This synonymous mutation does not alter the amino acid sequence directly but activates a cryptic splice donor site within exon 11, leading to aberrant pre-mRNA splicing. The abnormal splicing skips 150 nucleotides, causing a 50-amino-acid deletion near the C-terminus of prelamin A and generating the truncated isoform known as progerin. This specific mutation is found in approximately 90% of individuals with classic Hutchinson-Gilford progeria syndrome (HGPS), underscoring its predominant role in the disorder. It occurs as a heterozygous variant in the vast majority of cases, meaning it arises spontaneously in the affected individual rather than being inherited from a . Although the exhibits autosomal dominant —where a single mutant is sufficient to cause —its sporadic occurrence reflects the high rate of mutations, with rare instances of parental or mosaicism reported.

Protein Structure

Progerin is an abnormal variant of the lamin A protein, derived from prelamin A through defective post-translational processing. Normal prelamin A consists of 664 and features a C-terminal (CSIM, where C is 661, S is serine, I is , and M is ), which directs modifications essential for its maturation. This motif enables the initial attachment of a farnesyl group to 661 by farnesyltransferase (FTase), a key step in the protein's membrane association during early processing. The maturation of prelamin A proceeds through a series of enzymatic steps to produce soluble mature lamin A. Following farnesylation, the three C-terminal residues (SIM) are cleaved by the endoproteases RCE1 or ZMPSTE24, exposing the farnesylated cysteine for subsequent carboxymethylation by isoprenylcysteine carboxyl methyltransferase (ICMT). Finally, ZMPSTE24 performs a second cleavage, removing the terminal 15 amino acids (including the farnesyl-methyl-cysteine), resulting in a 646-amino-acid mature lamin A that lacks the lipid modification and integrates into the nuclear lamina. In progerin, a point mutation in the LMNA gene (c.1824C>T) activates a cryptic splice site, leading to an in-frame deletion of 50 amino acids (residues 607–656) and production of a 614-amino-acid protein. This deletion removes the RSYLLG motif, which is the recognition site for the second ZMPSTE24 cleavage, while preserving the CAAX motif. As a result, progerin undergoes farnesylation at cysteine 661, AAX cleavage, and methylation but retains the permanent farnesyl-methyl group at its C-terminus, preventing conversion to mature lamin A. This persistently farnesylated form accumulates at the nuclear envelope.

Cellular Localization

Normal lamin A, the mature form of the lamin A precursor protein, undergoes posttranslational that removes its C-terminal farnesyl group, rendering it soluble and enabling its assembly into the at the inner nuclear membrane. This processing allows mature lamin A to polymerize into a stable meshwork underlying the , providing structural support without persistent membrane anchoring. In contrast, progerin retains its farnesyl moiety due to a deletion of the ZMPSTE24 cleavage site, leading to persistent association with the inner nuclear membrane. This abnormal localization causes progerin to incorporate aberrantly into the , accumulating primarily at the nuclear rim and disrupting the lamina's architecture. The resulting irregular nuclear shape includes characteristic blebbing and lobulations, as progerin forms abnormal aggregates that deform the . Immunofluorescence studies have confirmed progerin's localization to the inner nuclear membrane, showing with lamin A/C and other lamina components in cells expressing the mutant protein. These experiments, often using antibodies specific to the progerin , reveal a punctate or patchy distribution at the nuclear periphery, distinct from the uniform lamina staining of wild-type lamin A. Low levels of progerin are also expressed in healthy aging cells through sporadic of the same cryptic splice site in the , with detecting its accumulation at the nuclear rim increasing with . Quantitation via RT-PCR and blotting indicates that progerin mRNA and protein levels rise progressively in normal fibroblasts, reaching detectable amounts in late-passage cells from elderly donors.

Physiological Role

Normal Lamin A Function

Lamin A is a type A protein that forms a dense meshwork underlying the inner membrane, contributing to the structural integrity of the . As part of the linker of nucleoskeleton and () complex, lamin A interacts with SUN-domain proteins and nesprins to connect the to the , facilitating positioning and force transmission across the . This integration is essential for maintaining and resisting mechanical stress, as evidenced by the increased fragility and deformability of nuclei in lamin A-deficient cells. In its structural capacity, lamin A organizes by tethering it to the periphery through lamina-associated domains (LADs), which are gene-poor regions typically associated with transcriptional repression. This supports proper architecture and mechanics during mechanotransduction, where external forces are propagated to influence responses. Beyond structure, lamin A plays key functional roles in regulating by modulating access to LADs and interacting with transcription factors. It also contributes to by providing docking sites for repair proteins, ensuring efficient resolution of DNA damage and genomic stability. Additionally, lamin A influences pathways, such as those involving ERK/MAP kinase and TGF-β/SMAD, by sequestering signaling molecules at the to fine-tune and . Expression of lamin A is developmentally regulated, with low or absent levels in most stem cells and early embryonic cells, but high expression in differentiated cells across various tissues, where it helps stabilize the differentiated state. Deficiency in lamin A, often due to mutations in the LMNA gene, disrupts these functions and leads to a spectrum of laminopathies, including muscular dystrophies, highlighting its critical role in .

Progerin Dysfunction

Progerin, a form of lamin A lacking 50 at its due to a splicing defect, disrupts the by forming abnormal aggregates that alter the mechanical properties of the . This leads to increased nuclear stiffness and reduced deformability, particularly under mechanical stress, as progerin sequesters wild-type and lamina-associated proteins, impairing the 's ability to withstand deformation. At the epigenetic level, progerin expression causes a loss of peripheral and alterations in modifications, including a significant reduction in the repressive mark , which destabilizes organization at the nuclear periphery. This loss occurs rapidly in progerin-expressing cells and is associated with derepression of genes normally silenced at the lamina, contributing to misregulated . Progerin impairs mechanisms, leading to the accumulation of DNA damage, including double-strand breaks, even in the absence of replication stress. It also induces dysfunction through altered 3D organization, promoting shortening and fragility, while increasing cellular sensitivity to via elevated (ROS) levels and disrupted antioxidant responses. In stem cells, particularly mesenchymal stem cells (MSCs), progerin disrupts self-renewal by downregulating key markers and reducing and capacities, while promoting premature toward osteogenic lineages at the expense of . This bias in lineage commitment contributes to impaired regeneration potential in progerin-expressing cells. Low-level expression of progerin occurs in normal aging cells and tissues, where it accumulates progressively and contributes to age-related nuclear defects, such as mild lobulation and alterations, linking it to physiological aging processes.

Association with Disease

Hutchinson-Gilford Progeria Syndrome

Hutchinson-Gilford progeria syndrome (HGPS) is a rare autosomal dominant characterized by the premature aging of children, resulting from mutations in the LMNA gene that lead to the production of progerin. The incidence of HGPS is approximately 1 in 4 million live births, with no reported differences based on sex or ethnicity. The global prevalence is estimated at 1 in 20 million individuals, with around 400 affected worldwide, though only 208 cases were identified as of June 2025. Symptoms typically begin to manifest between 6 and 12 months of age, following a normal infancy period, with progressive growth failure and the development of aged-appearing features. Key clinical manifestations include with severe and low body weight, scleroderma-like skin changes such as taut and pigmented skin with loss of elasticity, alopecia leading to near-total by age 2, and resulting in loss of subcutaneous fat particularly on the trunk and limbs. Cardiovascular complications, including and , are prominent and contribute significantly to morbidity. The average lifespan for individuals with HGPS is approximately 18.7 years with lonafarnib treatment (as of 2025), primarily due to , compared to a historical average of 14.5 years without treatment. Diagnosis of HGPS is primarily based on characteristic clinical features observed in , such as the combination of growth retardation, distinctive facial appearance with a small and prominent eyes, and sclerodermatous skin changes, and is confirmed through molecular for the specific LMNA (c.1824C>T) present in about 90% of cases. The syndrome was first described in 1886 by and further detailed between 1897 and 1904 by Hastings Gilford, after whom it is named.

Mechanisms of Cellular Pathology

Progerin, the aberrant lamin A variant, drives multi-organ pathology in Hutchinson-Gilford progeria syndrome (HGPS) primarily through induction of , DNA damage, and disrupted nuclear mechanics in affected tissues. This leads to progressive tissue degeneration, with cardiovascular complications accounting for over 80% of deaths, typically from or . In vascular pathology, progerin accumulation in aortic smooth muscle cells (SMCs) causes nuclear membrane ruptures, DNA damage, and senescence, resulting in SMC loss and vascular fibrosis. This depletion weakens arterial walls, promotes occlusive lesions, and culminates in myocardial infarction as the leading cause of mortality. Studies in HGPS patient-derived SMCs and mouse models confirm that progerin expression directly triggers these events, exacerbating atherosclerosis-like changes. Adipose tissue depletion in HGPS arises from progerin-induced in and preadipocytes, impairing and leading to . Rare progerin-expressing adipocytes contribute to progressive tissue loss over time, with ectopic fat accumulation in organs like the liver and heart as a compensatory response. This exhaustion disrupts and promotes chronic . Bone and skeletal abnormalities stem from progerin expression in osteoblasts, which dysregulates differentiation, reduces bone formation, and induces . This results in low bone mineral density, increased risk, and joint contractures due to altered Wnt signaling and defects. Progerin also affects osteocytes, leading to their premature loss and further skeletal fragility. Systemic effects include , driven by progerin modulation of IGF-1R/Akt signaling, which elevates insulin levels and impairs glucose metabolism. Hearing loss, often a mix of conductive and sensorineural types, arises from progerin-related damage to auditory structures, including cochlear elements, contributing to progressive auditory decline. Evidence from animal models, particularly LmnaG609G/G609G mice, recapitulates these HGPS phenotypes, including vascular loss, adipose depletion, and skeletal defects, with severity showing dose-dependent progression based on progerin levels. These models demonstrate that partial reduction of progerin ameliorates multi-organ , underscoring its causal role.

Clinical and Therapeutic Aspects

Diagnostic Features

Diagnosis of progerin-related conditions, particularly Hutchinson-Gilford syndrome (HGPS), relies on a combination of clinical evaluation, imaging, laboratory assessments, and histological examination, in addition to genetic confirmation via LMNA sequencing. Clinical is established through phenotypic features observed in affected children, typically manifesting within the first two years of life. Key diagnostic indicators include severe postnatal growth failure with height and weight below the third percentile, sclerodermatous skin changes, progressive leading to total by age two, and prominent superficial veins due to subcutaneous fat loss. Cardiovascular status is assessed via symptoms such as dyspnea or fatigue, while skeletal features like joint contractures and a high-pitched voice further support the diagnosis. A standardized clinical assessment, akin to a progeria score sheet, evaluates these elements—weight gain, skin integrity, and cardiovascular health—for early detection and monitoring disease progression. Imaging modalities play a crucial role in confirming systemic involvement. (MRI) and computed tomography (CT) angiography detect early , including arterial stenoses and calcifications in the carotid and intracranial vessels, which are prevalent even in young patients. evaluates cardiac function, revealing , valvular abnormalities, or reduced indicative of . Skeletal radiographs identify of the , osteolysis of the distal phalanges, and , aiding in the documentation of musculoskeletal pathology. Laboratory evaluations provide supportive evidence but lack pathognomonic biomarkers for progerin accumulation. Affected individuals typically exhibit normal (LDL) cholesterol and total levels, though (HDL) concentrations may decrease with age, contributing to cardiovascular risk. (IGF-1) levels are frequently below the normal range, correlating with growth deficiency, though variability exists across patients. Routine blood work, including lipid panels and assays, is recommended annually, but no specific circulating for progerin has been established. Histological analysis of skin biopsies from HGPS patients reveals characteristic nuclear abnormalities in dermal fibroblasts, including irregular nuclear envelopes, blebbing, and lobulation due to progerin accumulation at the nuclear periphery. These dystrophic changes, observable via electron microscopy or for lamin A/C, confirm cellular-level dysfunction and distinguish progerin effects from normal aging. Differential diagnosis involves distinguishing HGPS from other progeroid syndromes lacking LMNA mutations, such as caused by WRN gene defects, which presents later in adolescence with more pronounced cataracts and but less severe early growth failure. Conditions like mandibuloacral dysplasia or share scleroderma-like skin or growth issues but differ in onset, intellectual impact, or photosensitivity, necessitating comprehensive phenotyping to rule out mimics.

Treatment Strategies

Treatment of progerin-induced diseases, such as Hutchinson-Gilford progeria syndrome (HGPS), primarily relies on supportive and symptomatic management to alleviate symptoms like growth failure, joint stiffness, and cardiovascular risks, as no cure exists to eliminate progerin production. Supportive care emphasizes nutritional optimization through frequent small, high-calorie meals and daily multivitamins to combat and maintain hydration, particularly in warm environments or during activity. Physiotherapy, including physical and with active stretching, strengthening exercises, and , helps preserve joint mobility and prevent contractures, while shoe inserts address foot pain associated with . Low-dose aspirin (2-3 mg/kg/day) is routinely administered to reduce the risk of thrombotic events and neurovascular complications. Cardiovascular management is critical given the accelerated in HGPS, with strategies including regular monitoring of heart and vessel function via and lipid panels. Statins, such as pravastatin, are used to lower levels and support vascular health, often as part of broader dietary and pharmacologic interventions to mitigate and risks. Anti-congestive therapies, potentially incorporating agents like inhibitors for blood pressure control, address emerging , though evidence specific to HGPS remains supportive rather than definitive. Growth hormone therapy has been explored for weight gain and improved growth velocity in select HGPS cases, particularly when combined with nutritional support, but demonstrates limited long-term efficacy as benefits often wane and do not alter disease progression. Clinical trials targeting progerin reversal, such as the phase II study NCT00425607 evaluating farnesyltransferase inhibitors, have informed broader by highlighting potential for symptom amelioration, though outcomes vary. A multidisciplinary approach, coordinated by teams including endocrinologists, cardiologists, orthopedists, and nutritionists, is essential for holistic care, with guidelines from the Progeria Research Foundation recommending tailored protocols to enhance .

Lonafarnib Therapy

Lonafarnib is a farnesyltransferase (FTI) that targets progerin by preventing its farnesylation, a essential for its anchoring to the nuclear membrane. This inhibition reduces progerin accumulation, thereby improving nuclear morphology and mitigating associated cellular dysfunction in Hutchinson-Gilford (HGPS). A phase II conducted from 2007 to 2012 evaluated in 25 children with HGPS, administering the drug orally at doses escalating from 115 mg/m² to 150 mg/m² twice daily. The trial demonstrated efficacy in multiple domains: 36% of participants achieved at least a 50% increase in rate, and approximately 44% (8 of 18 evaluable patients) showed improvement in low-frequency sensorineural hearing by at least 10 . Additional benefits included a 35% reduction in vascular stiffness, as measured by , and increased bone mineral density in 76% of patients. Subsequent analysis from clinical trials and the International Progeria Registry, published in 2018, reported that was associated with a lower compared to untreated patients, with a of 0.23 (95% CI, 0.06-0.90; P=0.04) over a median follow-up of 2.2 years. Long-term follow-up data up to 11 years indicated a 2.5-year benefit for treated HGPS patients, extending the mean age of death from 14.5 years in untreated individuals to approximately 17 years. The standard dosing regimen is 150 mg/m² orally twice daily, following an initial 4-month period at 115 mg/m² if tolerated. Common side effects include and (affecting over 80% of patients), , , electrolyte abnormalities, and elevated liver enzymes, though the drug is generally well-tolerated with most adverse events being mild to moderate. The U.S. granted designation to for HGPS on April 18, 2011, and approved it as Zokinvy on November 20, 2020, for patients 12 months and older with HGPS and processing-deficient progeroid laminopathies. Prior to full approval, a compassionate use program provided access through expanded treatment protocols, allowing continued therapy for trial participants and others. Despite these advances, does not eliminate progerin production and exhibits variable patient responses, with some measures like incidence showing only preliminary improvements. Ongoing research explores its use in combination with other agents to enhance efficacy, though monotherapy remains the approved approach. As of 2025, clinical trials are investigating combinations of lonafarnib with agents such as .

Research and Future Directions

Experimental Models

Experimental models of progerin have been essential for elucidating its role in (HGPS) and related laminopathies, enabling the study of nuclear abnormalities such as blebbing and lobulation in controlled settings. These models span cellular, mammalian, and non-mammalian systems, providing insights into conserved mechanisms of progerin-induced dysfunction. In vitro cell models primarily utilize fibroblasts derived from HGPS patients, which exhibit characteristic defects due to progerin accumulation. These fibroblasts typically show 70-80% progerin-positive nuclei, with abnormal including blebs and irregular shapes that recapitulate patient-derived phenotypes. Such models have facilitated for therapeutic interventions targeting progerin farnesylation or expression. Induced pluripotent stem cell (iPSC) models have advanced the field by allowing the generation of progerin-expressing cells through editing of the LMNA gene in healthy iPSCs. This approach creates isogenic lines to isolate progerin effects from genetic background variations, enabling differentiation into disease-relevant cell types like cardiomyocytes or vascular cells for studying tissue-specific . For instance, /Cas9-mediated introduction of the HGPS mutation (c.1824C>T) in iPSCs produces progerin, leading to disruptions observable in derived lineages. Mouse models provide recapitulation of HGPS features, with the knock-in Lmna^{G609G/G609G} homozygous strain expressing progerin and displaying severe phenotypes such as growth retardation, alopecia, and shortened lifespan (median ~120 days). Heterozygous Lmna^{G609G/+} mice exhibit milder symptoms, including partial and bone abnormalities, modeling the dominant-negative effects of progerin at lower expression levels. Additionally, Zmpste24 mice serve as an analog model by accumulating unprocessed prelamin A, which farnesylates similarly to progerin and induces comparable progeroid traits like and cardiovascular defects. Non-mammalian models in and explore conserved lamin functions through mutations analogous to human progerin defects. In C. elegans, editing the baf-1 gene to mimic progeria-associated changes results in altered nuclear architecture, reduced lifespan, and stress sensitivity, highlighting evolutionary parallels in lamina stability. Drosophila models with missense mutations in the lamin Dm0 gene replicate nuclear envelope irregularities and tissue-specific dysfunctions, such as muscle weakness, underscoring progerin's impact on mechanotransduction across species. These models have proven utility in preclinical drug testing; for example, the farnesyltransferase inhibitor reduces nuclear blebbing in Lmna^{G609G/G609G} mice, improving vascular integrity and extending survival by ~20%. Similarly, in Zmpste24^{-/-} mice, ameliorates prelamin A accumulation and associated blebbing, validating farnesylation blockade as a therapeutic target.

Emerging Therapies

Investigational approaches targeting progerin accumulation beyond farnesyltransferase inhibition include , which block the cryptic splice site in the LMNA gene responsible for progerin production. Preclinical studies using morpholino in Hutchinson-Gilford progeria syndrome (HGPS)-like patient-derived fibroblasts have demonstrated that these agents prevent aberrant LMNA splicing, significantly reducing progerin levels by up to 80% and alleviating nuclear abnormalities and . Similar strategies employing peptide-conjugated phosphorodiamidate morpholinos have shown promise in blocking the splice site, further supporting their potential as a genetic therapeutic for reducing progerin in cellular models. Histone deacetylase (HDAC) inhibitors, such as sulforaphane derived from cruciferous vegetables, represent another emerging class of therapies that enhance progerin clearance through autophagy induction. In HGPS fibroblasts, sulforaphane treatment at 1 μM for 9 days reduced progerin levels by approximately 40%, increased proteasome activity, decreased nuclear blebbing, and lowered DNA damage markers, thereby rescuing cellular proliferation and protein homeostasis. Broader HDAC inhibitors like sodium butyrate have also mitigated progeroid phenotypes in Zmpste24-deficient mice, a model of progeria, by restoring histone H4 lysine 16 acetylation, reducing senescence in tissues such as the kidney, and extending median lifespan from 22 to 26 weeks when administered from birth. These findings highlight HDAC modulation's role in restoring heterochromatin organization and delaying aging-like features. Gene editing technologies, particularly CRISPR-Cas9-based editors, offer a direct method to correct the LMNA c.1824C>T mutation underlying HGPS. In patient-derived fibroblasts, editing achieved 80-90% mutation correction, reducing progerin expression 6- to 15-fold while preserving normal lamin A production, with minimal off-target edits. In vivo application via AAV delivery in HGPS mouse models resulted in up to 60% editing efficiency in the liver and 20-30% in heart and vascular tissues, leading to 49-86% progerin reduction, phenotypic rescue in vascular cells, and a 2.4-fold lifespan extension. Combination therapies pairing with other agents, such as pravastatin and , have been evaluated to address multifaceted aspects of . In a II involving 37 HGPS children treated for 40-52 months, this regimen improved weight gain or reduced carotid artery echodensity in 71% of participants and enhanced density and structure 1.5- to 1.8-fold compared to monotherapy, though no additional cardiovascular benefits were observed beyond those from alone. A I/II combining with everolimus (NCT02579044) was initiated but has unknown status as of its last verification in February 2023. The progerinin 2a , authorized by the FDA in 2024, began enrollment in late 2024 at , evaluating the drug in combination with (Zokinvy) in 10 patients with HGPS and progeroid laminopathies for , dosing, and preliminary as of mid-2025. Despite these advances, challenges persist, including efficient delivery to diverse tissues like the vasculature and , potential off-target effects in gene editing, and optimizing dosing to minimize toxicity. In 2025, additional preclinical advances have emerged. An RNA-based therapy using CRISPR-Cas13 delivered via reversed progeria symptoms, including and , in models by targeting progerin mRNA, as reported in July 2025. First-generation proteolysis targeting chimeras (PROTACs) designed to degrade progerin directly showed efficacy in cellular models, reducing progerin levels and defects, with preclinical testing ongoing as of October 2025. Furthermore, combining the JAK inhibitor with in progeria models reduced inflammation, improved vascular function, and extended lifespan by targeting progerin-induced inflammatory pathways, as demonstrated in a May 2025 study.