A comprehensive molecular study identified 12 complementation groups with 56 novel FANC gene variants in Indian Fanconi anemia subjects.

Fanconi anemia (FA) is a rare autosomal or X-linked genetic disorder characterized by chromosomal breakages, congenital abnormalities, bone marrow failure (BMF), and cancer. There has been a discovery of 22 FANC genes known to be involved in the FA pathway. This wide number of pathway components makes molecular diagnosis challenging for FA. We present here the most comprehensive molecular diagnosis of FA subjects from India. We observed a high frequency (4.42 ± 1.5 breaks/metaphase) of chromosomal breakages in 181 FA subjects. The major clinical abnormalities observed were skin pigmentation (70.2%), short stature (46.4%), and skeletal abnormalities (43.1%), along with a few minor clinical abnormalities. The combination of Sanger sequencing and Next Generation Sequencing could molecularly characterize 164 (90.6%) FA patients and identified 12 different complementation groups [FANCA (56.10%), FANCG (16.46%), FANCL (12.80%), FANCD2 (4.88%), FANCJ (2.44%), FANCE (1.22%), FANCF (1.22%), FANCI (1.22%), FANCN (1.22%), FANCC (1.22%), FANCD1 (0.61%) and FANCB (0.61%)]. A total of 56 novel variants were identified in our cohort, including a hotspot variant: a deletion of exon 27 in the FANCA gene and a nonsense variant at c.787 C>T in the FANCG gene. Our comprehensive molecular findings can aid in the stratification of molecular investigation in the diagnosis and management of FA patients.

Nitric oxide synthase-2 (NOS2) gene polymorphism c.1832C>T (Ser608Leu) associated with nitrosative stress in Fanconi anaemia.

Fanconi anemia (FA) occurs due to genomic instability with predisposition to bone marrow failure, phenotypic abnormalities and cancers. Though mutations in 22 genes leading to DNA repair defect have been identified, the cellular factor such as oxidative stress has also shown to be associated with FA. Nitrosative Stress (NS) is biochemically correlated to many oxidative stress related disorders and the NS as a pathological hallmark in FA has been so far overlooked. We carried out the study first time in Indian patients with FA with an objective to understand the role of NS in the pathogenesis of FA. The study was carried out in 70 FA subjects. The FA subjects were diagnosed by chromosomal breakage analysis. Molecular study was carried out by Next Generation Sequencing and Sanger sequencing. The 3-nitrotyrosine [3-NT] levels were estimated through enzyme-linked immuno-sorbent assay (ELISA) and the nitric oxide synthase genes- NOS1 (c.-420-34221G>A (rs1879417), c.-420-10205C>T (rs499776), c.4286+720G>C (rs81631)) and NOS2 (c.1823C>T (p. Ser608Leu) (rs2297518)) polymorphism were studied by direct sequencing. Chromosomal breakage analysis revealed a high frequency of chromosomal breaks (Mean chromosomal breakage-4.13 ± 1.5 breaks/metaphase) in 70 FA patients as compared to the control. Molecular studies revealed FANCA (58.34%), FANCG (18.34%) and FANCL (16.6%) complementation groups. The 3-nitrotyrosine [3-NT] levels showed to be significantly (p < 0.05) elevated in FA subjects when compared to the age match controls. Genotyping of the NOS2 gene c.1823C>T (p. Ser608Leu) (rs2297518), showed statistically significant (P < 0.05) association with FA. Elevated level of 3-NT is one of the cause of NS and NOS2 gene polymorphism associated with FA is an important target in the treatment regimen.

Severe telomere shortening in Fanconi anemia complementation group L.

Fanconi Anemia (FA) is a rare genetic disease with the incidence of 1 in 360,000 and is characterised by bone marrow failure, physical abnormalities, pancytopenia, and high frequency of chromosomal breakage and increased risk of evolving into malignancy. Telomere plays an important role in genomic stability, ageing process and cancers. Telomere shortening has been reported in FA. We studied telomere length in FA subjects and compared with complementation groups. Chromosomal breakage analysis from PHA stimulated, MMC induced peripheral blood culture was carried out in 37 clinically diagnosed FA. Molecular study of FANCA, G, and L was done through Sanger sequencing and next generation sequencing. Telomere length was estimated using real time quantitative polymerase chain reaction (qPCR) method. Student t-test was applied to test the significance. A high frequency of chromosomal breakage was observed in all the patients compared to healthy controls. We found significantly shorter telomere length in all the three complementation groups compare to age matched healthy controls. Among all complementation groups, FANCL showed severe telomere shortening (P value 0.0001). A negative correlation was observed between telomere length and chromosomal breakage frequency (R = -0.3116). Telomere shortening is not uncommon in FA subjects. However the telomere length shortening is different in complementation groups as FANCL showed severe telomere shortening in FA subjects. Though BM transplantation is essential for the management of the FA subjects, the telomere length can be considered as biological marker to understand the prognosis of the disease as FA subjects primarily treated with androgens.

A founder variant in the South Asian population leads to a high prevalence of FANCL Fanconi anemia cases in India.

Fanconi anemia (FA) is a rare genetic disorder characterized by bone marrow failure, predisposition to cancer, and congenital abnormalities. FA is caused by pathogenic variants in any of 22 genes involved in the DNA repair pathway responsible for removing interstrand crosslinks. FANCL, an E3 ubiquitin ligase, is an integral component of the pathway, but patients affected by disease-causing FANCL variants are rare, with only nine cases reported worldwide. We report here a FANCL founder variant, anticipated to be synonymous, c.1092G>A;p.K364=, but demonstrated to induce aberrant splicing, c.1021_1092del;p.W341_K364del, that accounts for the onset of FA in 13 cases from South Asia, 12 from India and one from Pakistan. We comprehensively illustrate the pathogenic nature of the variant, provide evidence for a founder effect, and propose including this variant in genetic screening of suspected FA patients in India and Pakistan, as well as those with ancestry from these regions of South Asia.

Making Time for Patients: Positive Impact of Direct Patient Reporting.

OBJECTIVE: Using a novel patient-centric approach, we assessed the impact of direct patient radiology reporting on the patient experience and patient perception of radiologists in a high-volume head and neck clinic. MATERIALS AND METHODS: A single head and neck surgeon at a large academic center identified prospective outpatients who met the following inclusion criteria: having received treatment for head and neck cancer and having recently undergone surveillance imaging using the Neck Imaging Reporting and Data System template at our institution. The surgeon introduced the concept and gave patients a survey with questions before and after the radiology consultation. The radiologist met with the patient in the head and neck clinic's examination room, explaining the role of the radiologist and reviewing imaging findings. RESULTS: Twenty-seven patients completed surveys. An improved understanding of the role of the radiologist was noted (41% of patients before consultation vs 67% after consultation). After the consultation, fewer patients (56-22%) wanted to hear from the referring physician only, and more patients wanted to hear from the radiologist only (26-44%) or from both the referring physician and the radiologist (19-33%). A total of 70-93% of patients had an improved understanding of imaging findings and follow-up recommendations after meeting with the radiologist. Most patients expressed an interest in reviewing future studies with a radiologist (93%) and found the consultation helpful (96%). CONCLUSION: Direct patient reporting by the radiologist is feasible in a high-volume head and neck clinic and has a positive impact on the patient experience. Major factors that enabled direct patient reporting included our embedded reading room and the use of a standardized reporting template. After the consultation, more patients wanted to receive information from the radiologist and had a better understanding of the imaging results.

Identification of novel target genes involved in Indian Fanconi anemia patients using microarray.

Fanconi anemia (FA) is a genetic disorder characterized by progressive bone marrow failure and a predisposition to cancers. Mutations have been documented in 15 FA genes that participate in the FA-BRCA DNA repair pathway, a fundamental pathway in the development of the disease and the presentation of its characteristic symptoms. Certain symptoms such as oxygen sensitivity, hematological abnormalities and impaired immunity suggest that FA proteins could participate in or independently control other pathways as well. In this study, we identified 9 DNA repair genes that were down regulated in a genome wide analysis of 6 Indian Fanconi anemia patients. Functional clustering of a total of 233 dysregulated genes identified key biological processes that included regulation of transcription, DNA repair, cell cycle and chromosomal organization. Microarray data revealed the down regulation of ATXN3, ARID4A and ETS-1, which were validated by RTPCR in a subsequent sample set of 9 Indian FA patients. Here we report for the first time a gene expression profile of Fanconi anemia patients from the Indian population and a pool of genes that might aid in the acquisition and progression of the FA phenotype.

Lowered expression levels of a tumor suppressor gene - caveolin-1 within dysregulated gene networks of Fanconi anemia.

Fanconi anemia (FA) is a genetic disorder characterized by progressive bone marrow failure and a predisposition to cancers like acute myeloid leukemia, lung and squamous cell carcinomas. DNA damage in a healthy cell activates the FA pathway where 15 individual FA proteins interact and function together to maintain genomic stability. The disruption of this pathway results in the characteristic cellular phenotype and clinical outcome of the disease. The diverse clinical symptoms of FA such as impaired immunity and predisposition to cancers may not be explained exclusively by a non-functional FA pathway. These symptoms could then be attributed to defects in other functions of the individual FA proteins. To identify the effects of a mutant FA protein, FANCC, a transcriptome analysis was carried out on a FANCC mutant cell line (EUFA 450) and its revertant isogenic control cell line (EUFA 450Rev). Microarray data revealed dysregulation of genes involved in regulation of cell death and immune response. This study reports for the first time, the lowered expression of a tumor suppressor gene - caveolin-1, in FANCC mutant cells. The downregulation of caveolin-1 can be significant as Fanconi anemia patients have an elevated predisposition to develop cancer.

Identification of the Fanconi anemia complementation group I gene, FANCI.

To identify the gene underlying Fanconi anemia (FA) complementation group I we studied informative FA-I families by a genome-wide linkage analysis, which resulted in 4 candidate regions together encompassing 351 genes. Candidates were selected via bioinformatics and data mining on the basis of their resemblance to other FA genes/proteins acting in the FA pathway, such as: degree of evolutionary conservation, presence of nuclear localization signals and pattern of tissue-dependent expression. We found a candidate, KIAA1794 on chromosome 15q25-26, to be mutated in 8 affected individuals previously assigned to complementation group I. Western blots of endogenous FANCI indicated that functionally active KIAA1794 protein is lacking in FA-I individuals. Knock-down of KIAA1794 expression by siRNA in HeLa cells caused excessive chromosomal breakage induced by mitomycin C, a hallmark of FA cells. Furthermore, phenotypic reversion of a patient-derived cell line was associated with a secondary genetic alteration at the KIAA1794 locus. These data add up to two conclusions. First, KIAA1794 is a FA gene. Second, this gene is identical to FANCI, since the patient cell lines found mutated in this study included the reference cell line for group I, EUFA592.