• BMB Reports
• /
• 제41권9호
• /
• pp.651-656
• /
• 2008

A mouse with cataract, Kec, was generated from N-ethyl-N-nitrosourea (ENU) mutagenesis. Cataract in the Kec mouse was observable at about 5 weeks after birth and this gradually progressed to become completely opaque by 12 weeks. Dissection microscopy revealed that vacuoles with a radial or irregular shape were located primarily in the cortex of the posterior and equatorial regions of the lens. At the late stage, the lens structure was distorted, but not ruptured. This cataract phenotype was inherited in an autosomal recessive manner. We performed a genetic linkage analysis using 133 mutant and 67 normal mice produced by mating Kec mutant (BALB/c) and F1 (C57BL/6 $\times$ Kec) mice. The Kec locus was mapped to the 3 cM region encompassed by D14Mit34 and D14Mit69. In addition we excluded coding sequences of 9 genes including Rcbtb2, P2ry5, Itm2b, Med4, Nudt15, Esd, Lcp1, Slc25a30, and 2810032E02Rik as the candidate gene that causes cataract in the Kec mouse.

• Clinical Nutrition Research
• /
• 제12권3호
• /
• pp.169-176
• /
• 2023

Glucose transporter type 1 (GLUT1) deficiency syndrome (DS) is a metabolic brain disorder caused by a deficiency resulting from SLC2A1 gene mutation and is characterized by abnormal brain metabolism and associated metabolic encephalopathy. Reduced glucose supply to the brain leads to brain damage, resulting in delayed neurodevelopment in infancy and symptoms such as eye abnormalities, microcephaly, ataxia, and rigidity. Treatment options for GLUT1 DS include ketogenic diet (KD), pharmacotherapy, and rehabilitation therapy. Of these, KD is an essential and the most important treatment method as it promotes brain neurodevelopment by generating ketone bodies to produce energy. This case is a focused study on intensive KD nutritional intervention for an infant diagnosed with GLUT1 DS at Gangnam Severance Hospital from May 2022 to January 2023. During the initial hospitalization, nutritional intervention was performed to address poor intake via the use of concentrated formula and an attempt was made to introduce complementary feeding. After the second hospitalization and diagnosis of GLUT1 DS, positive effects on the infant's growth and development, nutritional status, and seizure control were achieved with minimal side effects by implementing KD nutritional intervention and adjusting the type and dosage of anticonvulsant medications. In conclusion, for patients with GLUT1 DS, it is important to implement a KD with an appropriate ratio of ketogenic to nonketogenic components to supply adequate energy. Furthermore, individualized and intensive nutritional management is necessary to improve growth, development, and nutritional status.

• 대한유전성대사질환학회지
• /
• 제18권3호
• /
• pp.87-94
• /
• 2018

선천성 염소성 설사를 가진 환아에서 국소 분절 사구체경화증이 발생하여 말기 신장병으로 발전한 사례를 보고 하고자 한다. 20세 여자 환자로, 본원에서 출생 전 산전진단에서 양수과다 및 초음파 소견으로 선천성 염소성 설사가 의심되었으며, 출생 직후 확진 되어 신생아기 때부터 KCl 보충을 통하여 증상 조절을 시작하였다. 환아는 이후 특별한 건강의 문제가 없었으나 12세에 단백뇨가 관찰되었고, 16세때 본원에서 국소분절 사구체경과증 과 2기 만성신장병 진단을 받았다. 이후 보존적 치료를 하였으며, 지속적인 단백뇨에 대한 재 평가를 위하여 입원하게 되었다. 입원 후 확인된 검사에서 사구체여과율(GFR)은 4기 신장병으로 악화되어 있었으며 신생검에서도 국소분절 사구체신염으로 인한 만성 신장병이 재 확인 되었다. 환아 및 가족을 대상으로 시행한 유전자 검사(diagnostic exome sequencing)에서는 SLC26A3 유전자의(c.2063-1G>T) 동형 접합체 변이가 각각 부모에서 전달된 것을 확인하였다. 선천성 염소성 설사 환자는 적절한 전해질 보충에도 불구하고 신기능 손상이 되기 쉬운 경향이 있으며, 따라서 조기 진단 및 충분한 전해질 보충이 이루어지는 경우에서도 환자의 신장 기능에 대한 정기적 관찰 및 적절한 보조 치료가 필요할 것으로 사료된다.

• Genes and Genomics
• /
• 제40권12호
• /
• pp.1331-1338
• /
• 2018

Although there have been plenty of dominance deviation analysis, few studies have dealt with multiple phenotypes. Because researchers focused on multiple phenotypes (final weight and backfat thickness) of Landrace pigs, the classification of the genes was possible. With genome-wide association studies (GWASs), we analyzed the additive and dominance effects of the single nucleotide polymorphisms (SNPs). The classification of the pig genes into four categories (overdominance in final weight, overdominance in backfat thickness and overdominance in final weight, underdominance in backfat thickness, etc.) can enable us not only to analyze each phenotype's dominant effects, but also to illustrate the gene ontology (GO) analysis with different aspects. We aimed to determine the additive and dominant effect in backfat thickness and final weight and performed GO analysis. Using additive model and dominance deviation analysis in GWASs, Landrace pigs' overdominant and underdominant SNP effects in final weight and backfat thickness were surveyed. Then through GO analysis, we investigated the genes that were classified in the GWASs. The major GO terms of the underdominant effects in final weight and overdominant effects in backfat thickness were ion transport with the SLC8A3, KCNJ16, P2RX7 and TRPC3 genes. Interestingly, the major GO terms in the underdominant effects in the final weight and the underdominant effects in the backfat thickness were the regulation of ion transport with the STAC, GCK, TRPC6, UBASH3B, CAMK2D, CACNG4 and SCN4B genes. These results demonstrate that ion transport and ion transport regulation genes have distinct dominant effects. Through GWASs using the mode of linear additive model and dominance deviation, overdominant effects and underdominant effects in backfat thickness was contrary to each other in GO terms (ion transport and ion transport regulation, respectively). Additionally, because ion transport and ion transport regulation genes are associative with adipose tissue accumulation, we could infer that these two groups of genes had to do with unique fat accumulation mechanisms in Landrace pigs.