Kozlowski型脊椎干骺端发育不良1例报告

目的探讨Kozlowski型脊椎干骺端发育不良(SMDK)的临床特点及诊断。方法分析1例SMDK患者的临床特点、实验室检查及基因诊断,并复习相关文献。结果男性患儿8岁,病程6年余,临床表现为四肢指趾短粗,髋内翻畸形,膝外翻畸形,脊柱侧弯且前凸过度,严重的干骺端改变,TRPV4、NXX3-2基因杂合突变。结论典型的临床特征辅以基因诊断有助于及早发现和准确诊断SMDK。

TONSL基因复合杂合变异所致海绵状脊椎干骺端发育不良1例患儿的分析

目的探讨1例海绵状脊椎干骺端发育不良(SD)患儿的临床特征及遗传学病因。方法选取2022年8月因"身材矮小"就诊于临沂市人民医院的1例SD患儿作为研究对象。收集患儿的临床资料,对其进行全外显子组测序(WES),并对候选变异进行Sanger测序验证。结果患儿为9月龄女性,表现为身材矮小、面中部发育不良、关节松弛、膝内翻、长骨干骺端不规则、腰椎扁平伴凹陷等。WES显示其TONSL基因存在c.3088G>T(p.Glu1030*)和c.3053G>A(p.Arg1018His)复合杂合变异,分别遗传自表型正常的父亲和母亲,且既往均未见报道。根据美国医学遗传学与基因组学学会(ACMG)相关指南,c.3088G>T被判定为可能致病性变异(PVS1+PM2_Supporting),c.3053G>A被判定为临床意义未明变异(PM2_Supporting+PM3+PP3)。结论TONSL基因的c.3088G>T及c.3053G>A复合杂合变异可能是上述患儿的遗传学病因。上述发现为患儿的临床诊断与遗传咨询提供了依据。

一个SPONASTRIME型脊椎干骺端发育不良家系的临床特点及TONSL基因突变分析

目的对1个临床疑似SPONASTRIME型脊椎干骺端发育不良(SEMDSP)的家系进行临床特征分析和致病基因检测,为该病的临床诊断和遗传咨询提供分子依据。方法收集并分析该家系成员的临床资料,将病例2作为先证者进行全外显子组测序及变异位点分析,针对筛选出的候选靶基因突变位点用Sanger测序进行家系成员验证。结果该家系两患儿系姐弟,均因身材矮小来就诊,姐姐(病例1)初诊年龄为4岁2个月(身高88.6 cm),弟弟(病例2)初诊年龄为4岁4个月(身高81.6 cm)。两患儿临床表现为特殊面容,包括前额突出、面中部发育不良伴鼻梁凹陷、鼻孔上翻、眼距宽、内眦赘皮,毛发浓密,舌系带短,手掌手指粗短,无脊柱侧凸,父母表型正常。实验室检查结果提示两患儿均存在生长激素缺乏;影像学检查发现病例2骨龄明显落后,病例1桡骨远端可见纵向条纹但骨龄与实际年龄(5岁11个月)相符。两患儿均接受重组人生长激素治疗但疗效不佳。基因检测发现两患儿携带相同的TONSL基因复合杂合变异,包括父源性的c.1291-14_1291-11delCCTC杂合变异及母源性的c.1909_1920delACGCTGCAGCAG杂合变异。目前我国尚无SEMDSP家系报道,此外c.1909_1920delACGCTGCAGCAG为尚未报道的新变异。结论两患儿均诊断为SPONASTRIME型脊椎干骺端发育不良,上述复合杂合变异为该家系的遗传学病因。

GENETIC ENGINEERING NEURAL STEM CELL MODIFIED BY LENTIVIRUS FOR REPAIR OF SPINAL CORD INJURY IN RATS

Objective To explore the feasibility for therapy of spinal cord injury （SCI） by genetic engineering neural stem cell （NSC） modified by lentiviral vector. Methods Following the construction of the genetic engineering NSC modified by lentivirus to secrete both neurotrophic factor-3 （NT-3） and green fluorescence protein （GFP）, hemisection of spinal cord at the level of T10 was performed in 56 adult Wistar rats that were randomly divided into 4 groups （ n = 14 ）, namely 3 therapeutic groups and 1 control group. The therapeutic groups were dealed with NSC, genetic engineering NSC, and concentrated lentiviral supematant which carries both GFP and NT-3, respectively. Then used fluorescence microscope to detect the transgenic expression in vitro and in vivo, migration of the grafted cells in vivo, and used the Basso, Beattie, and Bresnahan （BBB） open-field locomotor test to assess the recovery of function. Results The transplanted cells could survive for long time in vivo and migrate for long distance. The stable transgenie expression could be detected in vivo. The hindlimb function of the injured rats in 3 therapeutic groups, especially those dealed with genetic engineering NSC, improved obviously. Concision It is feasible to combine NSC with lentivirus for the repair of SCI. NSC modified by lentivirus to deliver NT-3, acting as a source of neurotrophic factors and function cell in vivo, has the potential to participate in spinal cord repair.