This research adhered to the tenets of the Declaration of Helsinki. LCA patient families were ascertained through the King Khaled Eye Specialist Hospital (KKESH) in Riyadh, Saudi Arabia. Ophthalmologic information for each individual was scored as LCA or unaffected by at least one ophthalmologist at the time of referral to the hospital for evaluation, and then reviewed independently and examined independently by one of us (RAL). Detailed family histories and pedigrees of these families were obtained and confirmed through interviews with appropriate family members. Each subject, or a responsible adult on behalf of minors or wards, signed a Consent Statement for Participation approved by the Research Council at KKESH for these investigations and part of a larger program approved by the Baylor College of Medicine Affiliates Review Board for Human Subject Research. We obtained blood samples from subjects where appropriate. A total of 37 multi-generational consanguineous families with recessive LCA were collected; of 417 individuals from these families, 117 were affected. Pedigrees of the families with mutation identified in this study are shown in Figure 1 . Once recruited, blood samples were collected from all available family members, and DNA was extracted with a blood genomic DNA extraction kit (Qiagen, Valencia, CA), following the protocol provided by the manufacturer. 

Direct PCR and sequencing were used to screen the exons and splicing sites of the 13 known LCA genes, along with the immediately flanking intronic sequences, for point mutations and other small-scale sequence changes. DNA from one affected individual from each family was sequenced for both strands of all exons, including splicing sites, of all known LCA genes. In addition, the intronic region that contains a mutation that results in splicing of a cryptic exon downstream of exon 26 in CEP290 was also sequenced. ¹⁹ Each exon or intron was individually amplified from leukocyte DNA samples by PCR with primer pairs (primer sequences available on request). Exons longer than 500 base pairs were split into multiple amplicons. Each amplicon is 300 to 500 base pairs in length and was sequenced directly in both forward and reverse directions (ABI3730; AME Bioscience Ltd., Sharnbrook, Bedfordshire, UK). Each read was aligned to the reference sequence and base changes identified with a sequencing program (Sequencher; Gene Codes Corporation, Ann Arbor, MI). 

In addition to direct sequencing, families without mutations identified were further screened with STR markers around the 13 LCA genes and two loci. At least one marker near each gene and three markers near each locus were chosen from the GDB human genome database, ³⁰ as listed in Table 2 . Locations of these markers on the genome were determined by mapping the primer sequences to the human genome using bioinformatic software (BLAT; open source software). A universal primer was added to the end of each primer for fluorescent detection as described previously. ³¹ The size of each PCR fragment was determined with a machine (ABI3730; AME Bioscience Ltd.) and the data were analyzed with genotyping software (GeneMapper; Applied Biosystems, Inc., Foster City, CA) by standard procedures. 

To screen for mutations associated with an LCA phenotype in the 37 families in our collection, we selected one affected patient from each family for direct DNA sequencing. By comparison with the reference sequence, five different mutations were identified in nine of the 37 families (Table 3and Fig. 1 ), all of which are homozygous for the mutation. Of these nine families, five families (KKESH-014, -201, -203, -204, and -215) carry the same novel nonsense mutation at codon position 301 (Q301X) in TULP1. Two families, KKESH-048 and KKESH-082, carry mutations in RPE65. KKESH-082 has an RPE65 mutation reported previously (R91W), while KKESH-048 carries a novel mutation at the splice donor site of exon 6 (GGT→GCT). In addition, KKESH-039 carries a novel nonsense mutation (W93X) in CRB1. Finally, a previously reported disease-causing mutation (R660X) in GUCY2D was found in family KKESH-023. In addition to the two previously known mutations, all three novel mutations identified in this study are also likely to be pathogenic. First, the nonsense mutations in TULP1 and CRB1 both occur early in the coding region and are predicted by conceptual translation to result in severe protein truncations. Similarly, the mutation at the splice donor site of exon 6 in RPE65 causes inclusion of intron 6, leading to a frameshift and early termination. Second, clinical phenotypes observed in these subjects are consistent with the premise that these novel mutations are pathogenic. For example, patients from the KKESH-048 family that carry the mutation at the splicing site of exon 6 in RPE65 exhibit a RP-like phenotype, a previously reported feature for patients with mutations in RPE65 (Table 4) . Finally, all mutations we have identified are likely to be disease-causative, since each identified mutant allele cosegregates with LCA and no unaffected person in any pedigree has two mutant alleles. All available affected and unaffected family members have been genotyped for the identified mutation by direct sequencing. Consistent with the pattern of consanguinity, all LCA subjects are homozygous for the identified mutant allele while unaffected individuals are either heterozygous for the mutant allele or homozygous wild type. 

In addition to the five pathogenic mutations, five missense variations have also been identified during the initial sequencing of affected individuals (Table 3 , section 2). These variations are likely to represent benign polymorphisms. First, three of these variations (marked with rs number) occur frequently in normal populations as common SNPs as documented in the dbSNP database. ³² Second, although relatively rare, the other two novel variants do not segregate with LCA. Heterozygous affected and/or homozygous unaffected members have been found in the families, suggesting that these changes are not disease-causing. 

LCA is considered an early-onset genetic disease with high penetrance. To assess the degree of penetrance of the disease phenotype, we conducted phenotype-genotype correlation studies with nine Saudi Arabian families with the mutations identified above. The pedigree of each family is shown as Figure 1 . DNA from a total of 180 individuals (53 affected and 127 unaffected) from these nine families were genotyped for mutations identified above by direct sequencing of the causative mutations. Strikingly, all affected individuals are homozygous for the mutations while unaffected siblings are either heterozygous for the mutations or completely wild type. Therefore, a perfect correlation has been observed between the diagnosis and the underlying genotype. Furthermore, the ages of affected individuals range from 1 year to 27 years old, while the unaffected individuals range from 1 year to 65 years old at the time of evaluation, suggesting that LCA is an early-onset genetic disease with complete penetrance in these families. Detailed clinical phenotypic data for each affected in these nine families are listed in Table 4 . 

Although patients with LCA all show early loss of vision, the clinical phenotype among them varies. Recent studies have suggested that LCA can be classified into multiple categories and that each category may be caused by mutation in different sets of genes. ^{3 4 5 25} Consistent with this idea, examination of the clinical phenotype of 53 affected individuals in these nine LCA families revealed that patients with mutations in different genes exhibit distinct phenotypes (Table 4) . For example, patients carrying mutations in TULP1 often also show a sandy granular RPE periphery phenotype. In contrast, patients carrying mutations in GUCY2D show relatively normal retinal appearance with no or minimal vascular attenuation. Among the three GUCY2D patients, one also shows navigational vision and another has “fix and follow only” vision. At the same time, the clinical phenotype among patients with the same mutation often varies. For example, we have identified five LCA families carrying the same novel nonsense mutation at codon position 301 (Q301X) in TULP1 (Table 3) . Not all patients show an RP-like phenotype, whereas several patients from the family KKESH-204 show a novel phenotype of retinal peripheral whitening and patchy dots at the posterior edge distantly resembling fundus albipunctatus (Table 4) . 

It is possible that at least some of the remaining 28 families whose mutations have not been identified by direct sequencing of coding regions of known LCA genes actually carry disease-causative mutations in other functionally important parts of these genes, such as promoters or enhancers. To exclude all 13 known LCA disease genes from these families, we conducted further screening by STR markers (Table 2) . As all 28 Saudi families are consanguineous, one can exclude a family from carrying a mutation in a known gene if an affected individual is heterozygous for an STR marker linked to that gene. At least one marker near each LCA disease gene was selected to genotype one or more affected individual from each family. Segregation of these markers with disease was examined for each pedigree and in each case at least one marker was found to be heterozygous in the affected individuals, therefore allowing us to exclude all 28 families from the 13 known LCA genes. 

To test whether any of these 28 families who had been excluded from the 13 LCA genes’ maps to either of the two known LCA loci (LCA3 and LCA9) for which a specific gene has not been identified, three STR markers from each locus were tested with DNA from the affected individuals from these families (Table 2) . At least one subject of each family was found to be heterozygous for one or more STR marker(s) for the LCA9 locus, suggesting that none of the 28 families carry mutations in LCA9. In contrast, an affected individual from one family, KKESH-060, is homozygous for all markers from the LCA3 locus (Fig. 2) . To determine whether this family is indeed linked to the LCA3 locus, further genotyping of the other two affected and six unaffected members of the family was performed. We found that all three affected individuals are homozygous for all three STR markers in the LCA3 locus, whereas all unaffected individuals are either heterozygous or completely wild type. In addition to poor vision, all three affected individuals have non-recordable ERGs, hypermetropic astigmatism, and infantile nystagmus. Two patients (KKESH-060–04 and KKESH-060–06) also showed neuroretinal atrophy and markedly attenuated vessels of the fundi at the time (age) of examination. 

As one of the most severe causes of congenital blindness, both the clinical phenotype and the underlying molecular bases of the LCA disorders are very complex. To date, 14 genes and two loci have been linked to this disease, but these are estimated to account for only approximately 65% of all families of LCA. ^{5 19 25 26 27} Therefore, identification of all genes underlying LCA and the development of accurate molecular diagnoses are essential for understanding disease mechanisms and designing proper intervention. 

We found that the distribution of mutations in known LCA genes in subjects varies between populations. Previous mutation surveys of LCA patients have estimated that mutations in known LCA genes account for approximately 65% of all families. ^{5 19 25 26 27} Since most surveys were conducted in Caucasian populations, the fraction of patients carrying mutations in the currently known LCA genes could differ in other populations. To assess this issue, we conducted a comprehensive survey for mutations in 13 known LCA genes (GUCY2D, CRX, RPE65, TULP1, AIPL1, CRB1, RPGRIP1, LRAT, RDH12, IMPDH1, CEP290, RD3, and LCA5) and two loci (LCA3 and LCA9) in our LCA patient collection from Saudi Arabia. Interestingly, mutations in these 13 LCA genes were identified in only 24% of these families (9/37). This difference more likely reflects a difference in the populations rather than that a large portion of the Saudi families in our collection are related and share the same mutation. First, mutations in five known genes have been identified in nine families in our collection, and in most cases, only one or two families carry mutations in the same gene. Similarly, only two families have been mapped to the LCA3 locus. Second, three of the five mutations are novel mutations, indicating that the allele distribution is different from previous studies. For example, despite the fact that 8.6% of all LCA cases are due to mutation in CRB1 in previous surveys and more than 25 disease alleles have been reported, the 660R→Stop mutation identified in our study has not been identified previously. ³³ Third, none of these 37 families carry mutations in CEP290, the most frequently mutated gene in LCA patients in the European population. While it has been reported that mutations in CEP290 are involved in 21% of all cases in American families, no mutation has been found in this gene in our collection, despite both comprehensive sequencing and STR marker analysis. Interestingly, a recent survey of Italian LCA patients found that only 4% of patients have mutations in CEP290, further underscoring distinct mutation distributions even among different sub-populations of the same ethnicity. Fourth, based on our preliminary genome linkage scans, multiple novel LCA loci may be identified in the remaining 28 families who do not have mutations in the known LCA disease genes or loci, each of which is shared among only a few families (Chen R, unpublished data, 2008). Finally, historical information suggests that these Saudi families have widely divergent tribal origins (data not shown). Taken together, these results suggest that to uncover the entire complement of LCA disease genes, it is essential to examine diverse populations some of which may harbor different genetic variations and diverse mutant allele distributions. 

We have confirmed that LCA, as selected here, is indeed an early-onset genetic disease with complete penetrance, consistent with previous reports. In our study, we have identified nine multi-generation, consanguineous families, including a total of 180 individuals with 53 affected and 127 unaffected members, carrying mutations in known LCA genes. All members of these families have been genotyped for the causative mutations, and complete cosegregation between a homozygous mutant genotype and the disease phenotype has been observed (Fig. 1) . Such a feature of LCA makes it amenable to identifying mutations with homozygosity mapping with consanguineous families such as the ones that we have reported here. Together with the large sequencing capacity offered by the next generation sequencing technologies, such as the 454 and Solexa platforms, it becomes possible to conduct positional cloning starting with even small consanguineous families. 

With STR markers, we have identified another family in our collection, KKESH-060, whose disease maps to the LCA3 locus at 14q24. One LCA3 family, also from Saudi Arabia, has been reported previously. ²⁹ A LOD score of 3 was obtained with this new family, and as in the previously reported LCA3 family, all three affected members of this family are homozygous between STR markers D14S61 to D14S1066, a 13.4 Mb interval. In addition, both families present a very similar clinical phenotype. Interestingly, this new LCA3 family carries a different haplotype than the first LCA3 family based on STR markers, suggesting different origin of the mutant alleles. The identification of this second LCA3 family further supports the linkage between the LCA3 locus and the disease and will provide valuable reagents for identifying the underlying causative mutant gene. 

Complex genetic inheritance exists for many human disorders, including retinal diseases. ³⁴ For example, digenic tri-allelic inheritance has been observed in families segregating the Bardet-Biedl syndrome phenotype where inheritance of a mutation in a second gene is required for an individual who has two mutations in the first gene to exhibit a clinical phenotype or to modify the severity of the primary phenotype. ³⁴ However, we have not found evidence of tri-allelic inheritance in our inbred Saudi Arabian LCA families. No affected individuals from our cohort carry any coding or splicing mutations in other known LCA disease genes while all unaffected individuals are either wild-type or heterozygous for the mutation. Due to the relatively small sample size and homogenous genetic background, this result does not completely eliminate the possibility of complex inheritance for LCA in every instance. 

 

The authors thank Donna Munzy, Jerry Fowler, David Wheeler, and other staff members at the Human Genome Sequencing Center for technical assistance; John Cavender, MD, the Research Director of King Khalid Eye Specialist Hospital at the time of these studies; the Research Council of KKESH for its financial support and the staff of its Research Department for their diligent commitment to this program. In addition, we thank the families reported here for their willing cooperation with these studies.