Introduction

Age-related macular degeneration (AMD) is the commonest cause of blindness in the developed world.1 Genetic predisposition is thought to play a role and to date 19 genetic loci have been associated at a genome-wide level with an increased risk of developing AMD.2

Sorsby’s fundus dystrophy (SFD) is a rare autosomal dominant fundus dystrophy caused by mutations in the tissue inhibitor of metalloproteinase 3 (TIMP3) gene.3 It shares similar clinical features with AMD, including choroidal neovascularisation (CNV), although the age of onset is typically younger in the fourth decade of life.

We report the clinical phenotypes of three patients diagnosed at Southampton Eye Unit with bilateral neovascular AMD before the availability of anti-vascular endothelial growth factor (VEGF) therapies. All three were later found to be heterozygous for a predicted mutation, C113G, in the TIMP3 gene. These genotypes were identified through a collaboration with the International AMD Genomics Consortium (IAMDGC).4

Case reports

Case 1

A 56-year-old man presented with recent deterioration of vision in his left eye. Visual acuity was 6/9 in the right eye and 3/60 in the left eye. Examination revealed haemorrhage and subretinal fluid at the left macula. He had a family history of ‘macular degeneration’.

He then returned to the eye unit 4 years later with ‘advanced macular degeneration’ in the right eye. Visual acuity was now 2/60 in the right eye and hand movements in the left eye due to disciform scarring.

Case 2

A 64-year old man presented with sudden-onset reduced vision in his left eye. Visual acuity was 6/6 in the right eye and counting fingers in the left. Fluorescein angiography revealed a left subfoveal classic CNV. Both his grandmother and uncle had also been diagnosed with AMD.

Five years later his vision had decreased to 6/36 in the right eye. Fundus examination showed bilateral drusen with macular haemorrhage in the right eye and a left disciform scar (Figure 1a and b). Fluorescein angiography revealed a peripapillary CNV (Figure 1c and d). This was treated with radiotherapy, however by the following year his vision had decreased further to 6/60.

Figure 1
figure 1

Fundus photographs of patient 2 taken at the onset of right eye visual symptoms. Haemorrhage at the right macula (a), disciform scarring in the left eye (b) and bilateral drusen are shown. Early (c) and late (d) fluorescein angiography in the right eye revealed peripapillary choroidal neovascularisation.

Case 3

A 61-year old woman developed choroidal neovascularisation in her left eye, reducing her vision to hand movements. She had no family history of AMD. Six years later she developed symptoms in her right eye. Examination revealed bilateral drusen, disciform scarring in the left eye and haemorrhage at the right macula (Figure 2a and b). Indocyanine green angiography findings suggested right polypoidal choroidopathy (Figure 2c and d). Despite treatment with photodynamic therapy her visual acuity deteriorated from 6/36 to hand movements a year later.

Figure 2
figure 2

Fundus photographs of patient 3 taken at the onset of right eye visual symptoms, showing bilateral drusen, right eye macular haemorrhage (a) and a left disciform scar (b). Early (c) and late (d) indocyanine green angiography suggested polypoidal choroidopathy temporal to the right optic disc.

Discussion

TIMP3 is a 24 kD protein that inhibits matrix metalloproteinases. It is secreted by the retinal pigment epithelium (RPE) and deposits in Bruch’s membrane where it regulates extracellular matrix turnover,5 inhibits angiogenesis6 and regulates inflammation.7 Eleven distinct mutations to date have been associated with Sorsby's fundus dystrophy. All of these create unpaired cysteine residues in the C-terminal domain of the TIMP3 protein.8 This results in the formation of dimers which accumulate in Bruch’s membrane, compromising extracellular matrix turnover.9 RPE function is subsequently affected, leading to RPE atrophy and CNV.

The three patients described, diagnosed at the time with bilateral ‘neovascular AMD’, were found to be heterozygous for a predicted mutation, C113G, causing a Ser38Cys change and unpaired cysteine residue in the N terminus of TIMP3. The only other published report of this mutation describes two patients with strong family histories of early onset AMD who developed bilateral recurrent choroidal neovascularisation in their forties.8 By contrast, our three patients developed visual symptoms between 56 and 64 years, and one patient had no family history of AMD.

Recently presented work from the IAMDGC identified 28 heterozygotes for rare TIMP3 mutations and variants within 16 144 advanced AMD cases versus one heterozygote among >20 000 controls, which includes our three cases.4 The majority of these carried the C113G mutation and the average age of onset for macular disease was 65 years. This was significantly earlier than for non-carriers (77 years old, P<0.000001) but older than is typical for SFD.

We therefore conclude that the C113G TIMP3 mutation phenotype may mimic early onset neovascular AMD. Our report represents the first genotype–phenotype correlation of this mutation emerging from the IAMDGC. Cascade genetic testing for this rare highly penetrant allele in the relatives of patients with CNV diagnosed as early onset AMD may identify asymptomatic carriers who require close monitoring for future development of macular disease. This would aid prompt initiation of anti-VEGF therapy to prevent sight loss.10