Secretion Of Mutant Protein Research Articles

Epigallocatechin-3-gallate (EGCG) inhibits aggregation of pulmonary fibrosis associated mutant surfactant protein A2 via a proteasomal degradation pathway

Background/aimsEpigallocatechin-3-gallate (EGCG), a major catechin found in green tea, plays an important anti-tumor role and is involved in various other biological processes, such as, neuroprotection by prevention of aggregation of misfolded proteins generated because of genetic defects. Surfactant protein A2 mutations (G231V and F198S) have been identified to be associated with pulmonary fibrosis and lung cancer, and these mutations cause protein aggregation, instability as well as secretion deficiency. The present study focused on investigating the inhibitory effects of EGCG on aggregation of mutant SP-A2 and elucidating the potential mechanisms underlying this action. MethodsWild-type and mutant SP-A2 were transiently expressed in CHO-K1 cells. The aggregated and soluble proteins were separated into NP-40-insoluble and NP-40-soluble fractions. Protein stability was validated by chymotrypsin limited proteolysis assay. Western blot and RT-PCR were used to determine the protein and mRNA expression level, respectively. ResultsMutant SP-A2 alone or wild-type SP-A2 co-expressed with G231V formed NP-40-insoluble aggregates in CHO-K1 cells. EGCG significantly suppressed this aggregation and alleviated mutant SP-A2 accumulation in the ER. When combined with 4-PBA, EGCG treatment completely blocked mutant SP-A2 aggregate formation. Though secretion of mutant protein was not affected, EGCG facilitated protein instability in both wild-type and mutant protein. Importantly, MG132, a proteasome inhibitor, reversed EGCG-induced aggregate reduction. ConclusionsEGCG inhibits aggregation of misfolded SP-A2 via induction of protein instability and activation of proteasomal pathway for aggregate degradation.

IGSF10 mutations dysregulate gonadotropin-releasing hormone neuronal migration resulting in delayed puberty.

Early or late pubertal onset affects up to 5% of adolescents and is associated with adverse health and psychosocial outcomes. Self‐limited delayed puberty (DP) segregates predominantly in an autosomal dominant pattern, but the underlying genetic background is unknown. Using exome and candidate gene sequencing, we have identified rare mutations in IGSF10 in 6 unrelated families, which resulted in intracellular retention with failure in the secretion of mutant proteins. IGSF10 mRNA was strongly expressed in embryonic nasal mesenchyme, during gonadotropin‐releasing hormone (GnRH) neuronal migration to the hypothalamus. IGSF10 knockdown caused a reduced migration of immature GnRH neurons in vitro, and perturbed migration and extension of GnRH neurons in a gnrh3:EGFP zebrafish model. Additionally, loss‐of‐function mutations in IGSF10 were identified in hypothalamic amenorrhea patients. Our evidence strongly suggests that mutations in IGSF10 cause DP in humans, and points to a common genetic basis for conditions of functional hypogonadotropic hypogonadism (HH). While dysregulation of GnRH neuronal migration is known to cause permanent HH, this is the first time that this has been demonstrated as a causal mechanism in DP.‡

Genetic diseases of connective tissues: cellular and extracellular effects of ECM mutations

Tissue-specific extracellular matrices (ECMs) are crucial for normal development and tissue function, and mutations in ECM genes result in a wide range of serious inherited connective tissue disorders. Mutations cause ECM dysfunction by combinations of two mechanisms. First, secretion of the mutated ECM components can be reduced by mutations affecting synthesis or by structural mutations causing cellular retention and/or degradation. Second, secretion of mutant protein can disturb crucial ECM interactions, structure and stability. Moreover, recent experiments suggest that endoplasmic reticulum (ER) stress, caused by mutant misfolded ECM proteins, contributes to the molecular pathology. Targeting ER stress might offer a new therapeutic strategy.

Molecular characterization of coagulation factor XII deficiency in a Japanese family

We report the identification in a Japanese family of a novel homozygous W486C mutation in the protease domain of coagulation factor XII (FXII), which was associated with the reduction of plasma FXII activity and antigen level to less than 5% of normal. Sequences of each exon for FXII gene was analysed in family members by polymerase chain reaction (PCR) amplification followed by a direct sequencing method. Sequence analysis showed a homozygous substitution of G to C at nucleotide position 10587 (cDNA position 1458) in proband's FXII gene, resulting in a Trp to Cys substitution in the catalytic domain of FXII. PCR-fragment length polymorphism analysis of 55 healthy volunteers showed no such mutation. Transient expression of FXII in HK-293T cells and analysis of FXII antigen in culture media and cell lysates showed reduced secretion of mutant protein by more than 84% relative to that of wild type protein although the intracellular contents were similar. Our results suggest that the reduced secretion of FXII protein was due to incorrect folding caused by the introduction of Cys486. We designated this mutation as FXII Mie-1.

Protein C Deficiency caused by Homozygosity for a Novel PROC D180G Mutation – in vitro Expression and Structural Analysis of the Mutation

Homozygosity for a novel D180G mutation in the protease domain of protein C, associated with plasma protein C activity and antigen levels of 8% of normal was identified in a thrombosis prone family. Transient expression of protein C in HK-293 cells and analysis of protein C antigen in culture media and cell lysates showed that the secretion of mutant protein as compared with wild-type protein was reduced by 79% while the intracellular contents were similar. Computer analysis of the X-ray structure of activated protein C and of a theoretical model of the zymogen predicts that the mutation destabilises the molecule locally. Our results are compatible with a relatively unstable mutant molecule that could be trapped inside the cell and degraded. However, if secreted the mutant molecule could have a relatively normal catalytic activity and structure consistent with the plasma levels of protein C activity and the late onset of thrombosis.

Compound Heterozygous Protein C Deficiency Caused by Two Mutations, Arg-178 to Gin and Cys-331 to Arg, Leading to Impaired Secretion of Mutant Protein C

The protein C gene in a patient apparently homozygous for protein C deficiency was analyzed. Two different point mutations, each located in a different allele, were detected to reveal that the patient is a compound heterozygote. Mutation of Arg-178 (CGG) to Gln (CAG) [mutation I] was detected in exon VII, in the vicinity of activation peptide cleavage site by thrombin. Mutation of Cys-331 (TGC) to Arg (CGC) [mutation II] was found in exon IX, at one of the sites involved in disulfide bond formation in the catalytic domain of the heavy chain. The alteration of Cys-331 to Arg disables the formation of the disulfide bond and would alter the protein conformation. Transient expression assays using COS-7 cells transfected with protein C expression vectors containing each one of these two mutations suggested that each of the two mutations would lead to the protein C deficiency by an impairment of secretion of the respective mutant proteins.

Mutational analysis of mouse Wnt-1 identifies two temperature-sensitive alleles and attributes of Wnt-1 protein essential for transformation of a mammary cell line.

The proto-oncogene Wnt-1 encodes a cysteine-rich, secretory glycoprotein implicated in virus-induced mouse mammary cancer and intercellular signaling during vertebrate neural development. To attempt to correlate structural motifs of Wnt-1 protein with its function, 12 mutations were introduced singly and in several combinations into the coding sequence of Wnt-1 cDNA by site-directed mutagenesis. Mutant alleles in a retroviral vector were tested for their ability to transform the mouse mammary epithelial cell line C57MG in two ways: by direct infection of C57MG cells and by infection of NIH3T3 cells that serve as donors of Wnt-1 protein to adjacent C57MG cells in a secretion-dependent (paracrine) assay. In addition, the synthesis and secretion of mutant proteins were monitored in multiple cell types by immunological assays. Deletion of the signal peptide demonstrated that transformation in both direct and paracrine assays depends upon entry of Wnt-1 protein into the endoplasmic reticulum. Changes in potential proteolytic processing sites (two basic dipeptides and a probable signal peptidase cleavage site) did not adversely impair biological activity or protein processing and uncovered a second site for cleavage by signal peptidase. Replacement of each of the four asparagine-linked glycosylation sites did not affect transforming activity at normal temperatures, but one glycosylation site mutant was found to be temperature-sensitive for transformation. An allele encoding a protein that lacks all four glycosylation sites was also transformation competent. In two of four cases, substitution of serine for a cysteine residue impaired transforming activity at the usual temperature, and transformation was temperature sensitive in a third case, implying that at least some of the highly conserved cysteine residues are important for Wnt-1 function.