A novel PIK3R1 mutation of SHORT syndrome in a Chinese female with diffuse thyroid disease: a case report and review of literature.

BACKGROUND: SHORT syndrome is a rare genetic disease named with the acronyms of short stature, hyper-extensibility of joints, ocular depression, Rieger anomaly and teething delay. It is inherited in an autosomal dominant manner confirmed by the identification of heterozygous mutations in PIK3R1. This study hereby presents a 15-year-old female with intrauterine growth restriction, short stature, teething delay, characteristic facial gestalts who was identified a novel de novo nonsense mutation in PIK3R1. CASE PRESENTATION: The proband was admitted to our department due to irregular menstrual cycle and hirsutism with short stature, who had a history of intrauterine growth restriction and presented with short stature, teething delay, characteristic facial gestalts, hirsutism, and thyroid disease. Whole-exome sequencing and Sanger sequencing revealed c.1960C > T, a novel de novo nonsense mutation, leading to the termination of protein translation (p. Gln654*). CONCLUSIONS: This is the first case report of SHORT syndrome complicated with thyroid disease in China, identifying a novel de novo heterozygous nonsense mutation in PIK3R1 gene (p. Gln654*). The phenotypes are mildly different from other cases previously described in the literature, in which our patient presents with lipoatrophy, facial feature, and first reported thyroid disease. Thyroid disease may be a new clinical symptom of patients with SHORT syndrome.

Predictors of plasma cell disorders among African American patients: a community practice perspective.

African Americans have two- to three-fold higher incidence of multiple myeloma and MGUS compared to other ethnic groups in the USA. Some physicians often perform diagnostic evaluations for plasma cell disorders (PCD) in African American patients on the basis of hematological abnormalities (thrombocytopenia, leucopenia, etc.) even in the absence of traditional triggers such as anemia, renal impairment, hypercalcemia, hyperglobulinemia, and lytic bone disease. Whether these nontraditional triggers have any significant association with PCD in African American population is not known. In addition, whether this approach could detect more asymptomatic PCD than black population prevalence is questionable. Moreover, the association between traditional triggers and PCD particularly in blacks has not been clearly delineated. Hence, we have carried out a retrospective study in an attempt to answer these questions. Two hundred fifty-four patients were eligible. Multiple myeloma workup based on parameters other than traditional triggers did not detect more asymptomatic PCD than what is expected of black population prevalence (p = 0.19). Of traditional triggers, the finding of only anemia or hyperglobulinemia seemed to be nonspecific in black population (p = 0.17 and 0.85, respectively). However, the presence of serum creatinine >2 mg/dL or corrected serum calcium >10.5 mg/dL or a combination of traditional triggers appeared to be strongly predictive of PCD (odds ratio of 6.9, 4.2, and 3, respectively). The number of trigger variables was positively correlated with the likelihood of PCD (p < 0.001). Light-chain-only PCD, renal disease, and abnormal free light chain ratio seemed to be higher in black patients than their white counterparts.

Hypercalcemia in glycogen storage disease type I patients of Turkish origin.

Glycogen storage disease type I (GSD I) is an autosomal recessive disorder caused by defects in the glucose-6-phosphatase complex. Deficient activity in the glucose-6-phosphatase-a (G6Pase) catalytic unit characterizes GSD IA and defects in the glucose-6-phosphate transporter protein (G6PC) characterize GSD IB. The main clinical characteristics involve fasting hypoglycemia, hyperuricemia, hyperlactatemia, and hyperlipidemia. Hypercalcemia arose as an unknown problem in GSD I patients, especially in those with insufficient metabolic control. The aim of the present study was to obtain the prevalence of hypercalcemia and to draw attention to the metabolic complications of GSD I patients, including hypercalcemia in poor metabolic control. Hypercalcemia frequency and the affecting factors were studied cross-sectionally in 23 GSD I pediatric subjects. Clinical diagnosis of GSD I was confirmed in all patients either through documentation of deficient G6Pase enzyme activity levels on liver biopsy samples or through G6PC gene sequencing of DNA. Hypercalcemia was detected in 78.3% of patients with GSD I. Different from the previous report about hypercalcemia in a GSD IA patient who had R83H and 341delG mutations, we could not identify any genotype-phenotype correlation in our GSD I patients. Hyperlactatemia and hypertriglyceridemia correlated significantly with hypercalcemia. Furthermore, no differences in serum calcium concentrations could be demonstrated between patients with optimal metabolic control. We observed hypercalcemia in our series of GSD I patients during acute metabolic decompensation. Therefore, we speculate that hypercalcemia should be considered as one of the problems of GSD I patients during acute attacks. It may be related with prolonged lactic acidosis or may be a pseudohypercalcemia due to hyperlipidemia that can be seen in GSD I patients with poor metabolic control.