Homozygosity for two point mutations in the lipoprotein lipase (LPL) gene in a patient with familial LPL deficiency: LPL(Asp9–>Asn, Tyr262–>His)

Abstract

Familial lipoprotein lipase (LPL) deficiency is an inherited disorder of lipoprotein metabolism characterized by hypertriglyceridemia and recurrent episodes of abdominal pain and pancreatitis. We have studied the genetic basis of LPL deficiency in a 62-year-old black male with undetectable pre- and post-heparin plasma LPL mass and activity, DNA sequence analysis of the patient's LPL cDNA and gene as well as digestion with Bcl I and Asu I revealed that the proband is a homozygote for two separate gene defects. One mutation changed a G to an A, resulting in the conversion of amino acid 9 of the mature protein, aspartic acid (GAC), to asparagine (AAC). The second substitution, a C for a T, replaced tyrosine (TAC) at residue 262 with histidine (CAC). Northern blot analysis of monocyte-derived macrophage RNA demonstrated the presence of LPL mRNA of approximately normal size and quantity when compared to control. Expression of both mutations separately (pCMV-9 and pCMV-262) or in combination (pCMV-9+262) in human embryonal kidney-293 cells demonstrated that LPL-9 had approximately 80% the specific activity of wild type LPL, but LPL-262 and LPL-9+262 had no enzymic activity, thus establishing the functional significance of the LPL-262 defect. Despite an absolute deficiency of LPL mass and activity demonstrated by analysis of patient post-heparin plasma, in vitro expression of both LPL mutants was normal, suggesting that the absence of LPL in patient post-heparin plasma was a result of altered in vivo processing. Analysis of the heparin binding properties of the mutant enzymes by heparin-Sepharose affinity chromatography indicated that most of the LPL-262 mass was present in an inactive peak, which like the normal LPL monomer, eluted at 0.8 M NaCl. Thus, the Tyr262 --> His mutation may alter the stability of the LPL dimer, leading to the formation of inactive LPL-262 monomer which exhibits reduced heparin affinity. Based on these results, we propose that, in vivo, enhanced formation of LPL-9+262 monomer leads to abnormal binding of the mutant lipase to endothelial glycosaminoglycans ultimately resulting in enhanced catabolism of the mutant enzyme and lower enzyme mass in post-heparin plasma.