Distribution of mutations of acid β-D-glucosidase Gene (GBA) among 68 Russian patients with Gaucher’s disease

Gaucher disease (GD) is the most frequent lysosomal storage disease presenting in all populations. Mutations in the acid β-D-glucosidase gene (GBA) cause development of GD, resulting in a decrease or full loss of activity of this enzyme. We report here the results of the molecular-genetic analysis in 68 Russian GD patients from 65 families with the three types of this disease. The GD genotype has been completely elucidated in 58 patients and in all patients we have found at least one mutant allele (92.6%). Besides frequent mutations (p.N370S, c.1263_1317del (del55), p.L444P, p.R463C, Rec NciI) we have identified rare mutations p.R120W, p.R170C, p.R184W, p.G202R, Rec C (p.R120W; p.W184R; p.N188K; p.V191G; p.S196P; p.G202R; p.F213I), presenting in other populations of GD patients. The mutations p.P236T, p.L249Q, p.L288P, p.P319S, p.V352M, p.W381X, p.A384D identified in this study had not been described before. The GBA mutations identified in Russian patients have been compared with those found in patients of other European countries. Genotype-phenotype correlations in GD are discussed.     

Molecular defects in the α-N-acetylglucosaminidase gene in Italian Sanfilippo type B patients

Sanfilippo syndrome type B (mucopolysaccharidosis IIIB) is a rare autosomal recessive disorder characterized by the inability to degrade heparan sulfate because of a deficiency of the lysosomal enzyme alpha-N-acetylglucosaminidase (NAGLU). We performed mutation screening in a group of 20 patients, identyifing 28 mutations, 14 of which were novel (L35F, 204delC, 221insGCGCG, G82D, W156C, 507delC, IVS3+1G-->A, E336X, V501G, R520W, S534Y, W649C, 1953insGCCA, 2185delAGA). Four of these mutations were found in homozygosity and only one was seen in two different patients, showing the remarkable molecular heterogeneity of the disease. Mutation IVS3+1G-->A produces aberrant RNA splicing: it represents a base substitution from G to A of the invariant GT dinucleotides at the splicing donor site of intron 3 resulting in the skipping of exon 3 and both exons 2 and 3. Transient transfection of COS cells, by DNA mutagenized with NAGLU mutations, produced enzymatic molecules without activity, demonstrating the deleterious nature of the defects. Metabolic labeling of transfected mutants suggested a normal synthesis of the involved polypeptide for missense alterations, whereas increased protein or mRNA instability was shown for nonsense and most of the frameshift mutations.     

SLC34A3 mutations in patients with hereditary hypophosphatemic rickets with hypercalciuria predict a key role for the sodium-phosphate cotransporter NaPi-IIc in maintaining phosphate homeostasis

Hereditary hypophosphatemic rickets with hypercalciuria (HHRH) is a rare disorder of autosomal recessive inheritance that was first described in a large consanguineous Bedouin kindred. HHRH is characterized by the presence of hypophosphatemia secondary to renal phosphate wasting, radiographic and/or histological evidence of rickets, limb deformities, muscle weakness, and bone pain. HHRH is distinct from other forms of hypophosphatemic rickets in that affected individuals present with hypercalciuria due to increased serum 1,25-dihydroxyvitamin D levels and increased intestinal calcium absorption. We performed a genomewide linkage scan combined with homozygosity mapping, using genomic DNA from a large consanguineous Bedouin kindred that included 10 patients who received the diagnosis of HHRH. The disease mapped to a 1.6-Mbp region on chromosome 9q34, which contains SLC34A3, the gene encoding the renal sodium-phosphate cotransporter NaP(i)-IIc. Nucleotide sequence analysis revealed a homozygous single-nucleotide deletion (c.228delC) in this candidate gene in all individuals affected by HHRH. This mutation is predicted to truncate the NaP(i)-IIc protein in the first membrane-spanning domain and thus likely results in a complete loss of function of this protein in individuals homozygous for c.228delC. In addition, compound heterozygous missense and deletion mutations were found in three additional unrelated HHRH kindreds, which supports the conclusion that this disease is caused by SLC34A3 mutations affecting both alleles. Individuals of the investigated kindreds who were heterozygous for a SLC34A3 mutation frequently showed hypercalciuria, often in association with mild hypophosphatemia and/or elevations in 1,25-dihydroxyvitamin D levels. We conclude that NaP(i)-IIc has a key role in the regulation of phosphate homeostasis.     

Genetic identification of residues involved in association of alpha and beta G-protein subunits.

The GPA1, STE4, and STE18 genes of Saccharomyces cerevisiae encode the alpha, beta, and gamma subunits, respectively, of a G protein involved in the mating response pathway. We have found that mutations G124D, W136G, W136R, and delta L138 and double mutations W136R L138F and W136G S151C of the Ste4 protein cause constitutive activation of the signaling pathway. The W136R L138F and W136G S151C mutant Ste4 proteins were tested in the two-hybrid protein association assay and found to be defective in association with the Gpa1 protein. A mutation at position E307 of the Gpa1 protein both suppresses the constitutive signaling phenotype of some mutant Ste4 proteins and allows the mutant alpha subunit to physically associate with a specific mutant G beta subunit. The mutation in the Gpa1 protein is adjacent to the hinge, or switch, region that is required for the conformational change which triggers subunit dissociation, but the mutation does not affect the interaction of the alpha subunit with the wild-type beta subunit. Yeast cells constructed to contain only the mutant alpha and beta subunits mate and respond to pheromones, although they exhibit partial induction of the pheromone response pathway. Because the ability of the modified G alpha subunit to suppress the Ste4 mutations is allele specific, it is likely that the residues defined by this analysis play a direct role in G-protein subunit association.     

Structural effects of clinically observed mutations in JAK2 exons 13-15: comparison with V617F and exon 12 mutations

Background  

The functional relevance of many of the recently detected JAK2 mutations, except V617F and exon 12 mutants, in patients with chronic myeloproliferative neoplasia (MPN) has been significantly overlooked. To explore atomic-level explanations of the possible mutational effects from those overlooked mutants, we performed a set of molecular dynamics simulations on clinically observed mutants, including newly discovered mutations (K539L, R564L, L579F, H587N, S591L, H606Q, V617I, V617F, C618R, L624P, whole exon 14-deletion) and control mutants (V617C, V617Y, K603Q/N667K).     

Disease-related mutations in cytochrome c oxidase studied in yeast and bacterial models.

Mitochondrial cytochrome c oxidase is a key protonmotive component of the respiratory chain. Mutations in the mitochondrially-encoded subunits of the complex have been reported in association with a range of diseases. In this work we used yeast and bacterial mutants to assess the effect of human mutations in subunit 1 (L196I) and subunit 3 (G78S, A200T, Delta F94-F98, F251L and W249Stop). While the stop mutation at the C-terminus of subunit 3 and the short deletion were highly deleterious and abolished the assembly of the mitochondrial enzyme, the four missense mutations caused little or no effect on the respiratory function. Detailed analysis of G78S, A200T and Delta F94-F98 in Rhodobacter sphaeroides confirmed and extended these observations. We show in this study that the combination of yeast and bacterial models is a useful tool to elucidate the effect of mutations in the catalytic core of cytochrome oxidase. The yeast enzyme is highly similar to the human enzyme and provides a good model to assess the deleterious effect of reported mutations. The bacterial system allows detailed biochemical analysis of the effect of the mutations on the function and assembly of the catalytic core of the enzyme.     

Structural basis for type I and type II deficiencies of antithrombotic plasma protein C: Patterns revealed by three-dimensional molecular modelling of mutations of the protease domain

Familial deficiency of protein C is associated with inherited thrombophilia. To explore how specific missense mutations might cause observed clinical phenotypes, known protein C missense mutations were mapped onto three-dimensional homology models of the protein C protease domain, and the implications for domain folding and structure were evaluated. Most Type I missense mutations either replaced internal hydrophobic residues (I201T, L223F, A259V, A267T, A346T, A346V, G376D) or nearby interacting residues (I403M, T298M, Q184H), thus disrupting the packing of internal hydrophobic side chains, or changed hydrophilic residues, thus disrupting ion pairs (N256D, R178W). Mutations (P168L, R169W) at the activation site destabilized the region containing the activation peptide structure. Most Type II mutations involved solvent-exposed residues and were clustered either in a positively charged region (R147W, R157Q, R229Q, R352W) or were located in or near the active site region (S252N, D359N, G381S, G391S, H211Q). The cluster of arginines 147, 157, 229, and 352 may identify a functionally important exosite. Identification of the spatial relationships of natural mutations in the protein C model is helpful for understanding manifestations of protein C deficiency and for identification of novel, functionally important molecular features and exosites. © 1994 John Wiley & Sons, Inc.     

Fabry disease: twenty novel alpha-galactosidase A mutations and genotype-phenotype correlations in classical and variant phenotypes

BACKGROUND: Fabry disease (OMIM 301500) is an X-linked inborn error of glycosphingolipid metabolism resulting from mutations in the alpha-galactosidase A (alpha-Gal A) gene. The disease is phenotypically heterogeneous with classic and variant phenotypes. To assess the molecular heterogeneity, define genotype/phenotype correlations, and for precise carrier identification, the nature of the molecular lesions in the alpha-Gal A gene was determined in 40 unrelated families with Fabry disease. MATERIALS AND METHODS: Genomic DNA was isolated from affected males or obligate carrier females and the entire alpha-Gal A coding region and flanking sequences were amplified by PCR and analyzed by automated sequencing. Haplotype analyses were performed with polymorphisms within and flanking the alpha-Gal A gene. RESULTS: Twenty new mutations were identified (G43R, R49G, M72I, G138E, W236X, L243F, W245X, S247C, D266E, W287C, S297C, N355K, E358G, P409S, g1237del15, g10274insG, g10679insG, g10702delA, g11018insA, g11185-delT), each in a single family. In the remaining 20 Fabry families, 18 previously reported mutations were detected (R49P, D92N, C94Y, R112C [two families], F113S, W162X, G183D, R220X, R227X, R227Q, Q250X, R301X, R301Q, G328R, R342Q, E358K, P409A, g10208delAA [two families]). Haplotype analyses indicated that the families with the R112C or g10208delAA mutations were not related. The proband with the D266E lesion had a severe classic phenotype, having developed renal failure at 15 years. In contrast, the patient with the S247C mutation had a variant phenotype, lacking the classic manifestations and having mild renal involvement at 64 years. CONCLUSIONS: These results further define the heterogeneity of alpha-Gal A mutations causing Fabry disease, permit precise heterozygote detection and prenatal diagnosis in these families, and provide additional genotype/phenotype correlations in this lysosomal storage disease.     

LITAF Mutations Associated with Charcot-Marie-Tooth Disease 1C Show Mislocalization from the Late Endosome/Lysosome to the Mitochondria

Charcot-Marie-Tooth (CMT) disease is one of the most common heritable neuromuscular disorders, affecting 1 in every 2500 people. Mutations in LITAF have been shown to be causative for CMT type 1C disease. In this paper we explore the subcellular localization of wild type LITAF and mutant forms of LITAF known to cause CMT1C (T49M, A111G, G112S, T115N, W116G, L122V and P135T). The results show that LITAF mutants A111G, G112S, W116G, and T115N mislocalize from the late endosome/lysosome to the mitochondria while the mutants T49M, L122V, and P135T show partial mislocalization with a portion of the total protein present in the late endosome/lysosome and the remainder of the protein localized to the mitochondria. This suggests that different mutants of LITAF will produce differing severity of disease. We also explored the effect of the presence of mutant LITAF on wild-type LITAF localization. We showed that in cells heterozygous for LITAF, CMT1C mutants T49M and G112S are dominant since wild-type LITAF localized to the mitochondria when co-transfected with a LITAF mutant. Finally, we demonstrated how LITAF transits to the endosome and mitochondria compartments of the cell. Using Brefeldin A to block ER to Golgi transport we demonstrated that wild type LITAF traffics through the secretory pathway to the late endosome/lysosome while the LITAF mutants transit to the mitochondria independent of the secretory pathway. In addition, we demonstrated that the C-terminus of LITAF is necessary and sufficient for targeting of wild-type LITAF to the late endosome/lysosome and the mutants to the mitochondria. Together these data provide insight into how mutations in LITAF cause CMT1C disease.     

Dominant and recessive distal renal tubular acidosis mutations of kidney anion exchanger 1 induce distinct trafficking defects in MDCK cells

Distal renal tubular acidosis (dRTA), a kidney disease resulting in defective urinary acidification, can be caused by dominant or recessive mutations in the kidney Cl-/HCO3- anion exchanger (kAE1), a glycoprotein expressed in the basolateral membrane of alpha-intercalated cells. We compared the effect of two dominant (R589H and S613F) and two recessive (S773P and G701D) dRTA point mutations on kAE1 trafficking in Madin-Darby canine kidney (MDCK) epithelial cells. In contrast to wild-type (WT) kAE1 that was localized to the basolateral membrane, the dominant mutants (kAE1 R589H and S613F) were retained in the endoplasmic reticulum (ER) in MDCK cells, with a few cells showing in addition some apical localization. The recessive mutant kAE1 S773P, while misfolded and largely retained in the ER in non-polarized MDCK cells, was targeted to the basolateral membrane after polarization. The other recessive mutants, kAE1 G701D and designed G701E, G701R but not G701A or G701L mutants, were localized to the Golgi in both non-polarized and polarized cells. The results suggest that introduction of a polar mutation into a transmembrane segment resulted in Golgi retention of the recessive G701D mutant. When coexpressed, the dominant mutants retained kAE1 WT intracellularly, while the recessive mutants did not. Coexpression of recessive G701D and S773P mutants in polarized cells showed that these proteins could interact, yet no G701D mutant was detected at the basolateral membrane. Therefore, compound heterozygous patients expressing both recessive mutants (G701D/S773P) likely developed dRTA due to the lack of a functional kAE1 at the basolateral surface of alpha-intercalated cells.     

A specific tryptophan in the I-II linker is a key determinant of beta-subunit binding and modulation in Ca(V)2.3 calcium channels

The ancillary beta subunits modulate the activation and inactivation properties of high-voltage activated (HVA) Ca(2+) channels in an isoform-specific manner. The beta subunits bind to a high-affinity interaction site, alpha-interaction domain (AID), located in the I-II linker of HVA alpha1 subunits. Nine residues in the AID motif are absolutely conserved in all HVA channels (QQxExxLxGYxxWIxxxE), but their contribution to beta-subunit binding and modulation remains to be established in Ca(V)2.3. Mutations of W386 to either A, G, Q, R, E, F, or Y in Ca(V)2.3 disrupted [(35)S]beta3-subunit overlay binding to glutathione S-transferase fusion proteins containing the mutated I-II linker, whereas mutations (single or multiple) of nonconserved residues did not affect the protein-protein interaction with beta3. The tryptophan residue at position 386 appears to be an essential determinant as substitutions with hydrophobic (A and G), hydrophilic (Q, R, and E), or aromatic (F and Y) residues yielded the same results. beta-Subunit modulation of W386 (A, G, Q, R, E, F, and Y) and Y383 (A and S) mutants was investigated after heterologous expression in Xenopus oocytes. All mutant channels expressed large inward Ba(2+) currents with typical current-voltage properties. Nonetheless, the typical hallmarks of beta-subunit modulation, namely the increase in peak currents, the hyperpolarization of peak voltages, and the modulation of the kinetics and voltage dependence of inactivation, were eliminated in all W386 mutants, although they were preserved in part in Y383 (A and S) mutants. Altogether these results suggest that W386 is critical for beta-subunit binding and modulation of HVA Ca(2+) channels.     

Functional characterization of sonic hedgehog mutations associated with holoprosencephaly

Mutations of the developmental gene Sonic hedgehog (SHH) and alterations of SHH signaling have been associated with holoprosencephaly (HPE), a rare disorder characterized by a large spectrum of brain and craniofacial anomalies. Based on the crystal structure of mouse N-terminal and Drosophila C-terminal hedgehog proteins, we have developed three-dimensional models of the corresponding human proteins (SHH-N, SHH-C) that have allowed us to identify within these two domains crucial regions associated with HPE missense mutations. We have further characterized the functional consequences linked to 11 of these mutations. In transfected HEK293 cells, the production of the active SHH-N fragment was dramatically impaired for eight mutants (W117R, W117G, H140P, T150R, C183F, L271P, I354T, A383T). The supernatants from these cell cultures showed no significant SHH-signaling activity in a reporter cell-based assay. Two mutants (G31R, D222N) were associated with a lower production of SHH-N and signaling activity. Finally, one mutant harboring the A226T mutation displays an activity comparable with the wild-type protein. This work demonstrates that most of the HPE-associated SHH mutations analyzed have a deleterious effect on the availability of SHH-N and its biological activity. However, because of the lack of correlation between genotype and phenotype for SHH-associated mutations, our study suggests that other factors intervene in the development of the spectrum of HPE anomalies.     

Analysis of Trafficking,Stability and Function of Human Connexin 26 Gap Junction Channels with Deafness-Causing Mutations in the Fourth Transmembrane Helix

Human Connexin26 gene mutations cause hearing loss. These hereditary mutations are the leading cause of childhood deafness worldwide. Mutations in gap junction proteins (connexins) can impair intercellular communication by eliminating protein synthesis, mis-trafficking, or inducing channels that fail to dock or have aberrant function. We previously identified a new class of mutants that form non-functional gap junction channels and hemichannels (connexons) by disrupting packing and inter-helix interactions. Here we analyzed fourteen point mutations in the fourth transmembrane helix of connexin26 (Cx26) that cause non-syndromic hearing loss. Eight mutations caused mis-trafficking (K188R, F191L, V198M, S199F, G200R, I203K, L205P, T208P). Of the remaining six that formed gap junctions in mammalian cells, M195T and A197S formed stable hemichannels after isolation with a baculovirus/Sf9 protein purification system, while C202F, I203T, L205V and N206S formed hemichannels with varying degrees of instability. The function of all six gap junction-forming mutants was further assessed through measurement of dye coupling in mammalian cells and junctional conductance in paired Xenopus oocytes. Dye coupling between cell pairs was reduced by varying degrees for all six mutants. In homotypic oocyte pairings, only A197S induced measurable conductance. In heterotypic pairings with wild-type Cx26, five of the six mutants formed functional gap junction channels, albeit with reduced efficiency. None of the mutants displayed significant alterations in sensitivity to transjunctional voltage or induced conductive hemichannels in single oocytes. Intra-hemichannel interactions between mutant and wild-type proteins were assessed in rescue experiments using baculovirus expression in Sf9 insect cells. Of the four unstable mutations (C202F, I203T, L205V, N206S) only C202F and N206S formed stable hemichannels when co-expressed with wild-type Cx26. Stable M195T hemichannels displayed an increased tendency to aggregate. Thus, mutations in TM4 cause a range of phenotypes of dysfunctional gap junction channels that are discussed within the context of the X-ray crystallographic structure.     

Characterization of Escherichia coli ATP synthase beta-subunit mutations using a chromosomal deletion strain.

(1) We constructed Escherichia coli strain JP17 with a deletion in the ATP synthase beta-subunit gene. JP17 is completely deficient in ATP synthase activity and expresses no beta-subunit. Expression of normal beta-subunit from a plasmid restores haploid levels of ATP synthase in membranes. JP17 was shown to be efficacious for studies of beta-subunit mutations. Site-directed mutants were studied directly in JP17. Randomly generated chromosomal mutants were identified by PCR and DNA sequencing, cloned, and expressed in JP17. (2) Eight novel mutations occurring within the putative catalytic nucleotide-binding domain were characterized with respect to their effects on catalysis and structure. The mutations beta C137S, beta G152D, beta G152R, beta E161Q, beta E161R, and beta G251D each impaired catalysis without affecting enzyme assembly or oligomeric structure and are of interest for future studies of catalytic mechanism. The mutations beta D301V and beta D302V, involving strongly conserved carboxyl residues, caused oligomeric instability of F1. However, growth characteristics of these mutants suggested that neither carboxyl side chain is critical for catalysis. (3) The mutations beta R398C and beta R398W rendered ATP synthase resistant to aurovertin, giving strong support to the view that beta R398 is a key residue in the aurovertin-binding site. Neither beta R398C or beta R398W impaired catalysis significantly.     

Recognition sequence 2 (residues 60-71) plays a role in oligomerization and exchange dynamics of alphaB-crystallin

Previously, using the peptide scan method, we have determined that residues 42-57 and 60-71 in alphaB-crystallin (TSLSPFYLRPPSFLRA, named recognition sequence 1 or RS-1, and WFDTGLSEMRLE, named recognition sequence 2 or RS-2) are involved in interaction with alphaA-crystallin. To understand the significance of the RS-2 region in interactions between alphaA- and alphaB-crystallins, W60R, F61N, and S66G mutants of alphaB-crystallin were made and tested for their ability to interact with alphaA-crystallin. W60R and S66G mutations increased the oligomeric size of alphaB-crystallin by 1.6- and 2.7-fold respectively, whereas the F61N mutation had no effect. The tryptophan fluorescence intensity of alphaBS66G was 1.5-fold higher than that for the wild type. The intrinsic fluorescence of alphaBF61N was marginally lower than that of alphaB, whereas the fluorescence intensity of alphaBW60R decreased by 40% compared with that of alphaB. The relative availability of hydrophobic sites in the mutants was in the following order: alphaBS66G > alphaB = alphaBF61N = alphaBW60R. The far-UV CD profiles for the wild type and alphaB-crystallin mutants indicated no significant changes in their secondary structures, except for alphaBS66G, which showed an increase in alpha-helical content. The near-UV CD profiles of alphaBW60R and alphaBF61N were nearly similar to that of wild type alphaB. On the other hand, alphaBS66G beyond 270 nm exhibited a signature completely different from that of wild type alphaB. Mutations did not alter the chaperone-like activity of these proteins. The W60R mutation did not affect the rate of subunit exchange between alphaB- and alphaA-crystallins. On the other hand, the S66G mutation increased the subunit exchange rate by 100%, whereas the F61N mutation decreased the rate of subunit exchange between alphaB- and alphaA-crystallins by 36%. Our results establish the importance of residues 60-71 in oligomerization of alphaB-crystallin and subunit interaction between alphaB- and alphaA-crystallins.     

Intracellular distribution, assembly and effect of disease-associated connexin 31 mutants in HeLa cells

Mutations in connexin 31 （Cx31） are associated with erythrokeratodermia variabilis （EKV）,hearing impairment and peripheral neuropathy; however, the pathological mechanism of Cx31 mutants remains unknown. This study analyzed 11 disease-associated Cx31 variants and one non-disease-associated Cx31 variant and compared their intracellular distribution and assembly in HeLa cells and their effect on these cells. The fluorescent localization assay showed no gap junction plaque formation in the cells expressing the recessive EKV-associated mutant （L34P） and four hearing impairment-associated mutants （66delD,141delI, R180X and E183K）, significantly reduced plaque formation in the cells with five EKV-associated dominant mutants （G12R, G12D, R42P, C86S and F137L） and no obvious change in the cells with two other mutants （I 141V and 652del 12）. Immunoblotting analysis showed that 12 mutated Cx31 s, like WTCx31, are able to form the Triton X-100 insoluble complex; however, the quantity of Triton X-100 insoluble complex in the transfected HeLa cells varied among different Cx31 mutants. Additionally, the expression of five EKV-associated dominant mutants （G12R, G12D, R42P, C86S and F137L） caused cell death in HeLa cells. However, the five heating impairment-associated mutants did not induce cell death. The above results suggest that disease-associated mutants gain deleterious functions differentially. In summary, diseaseassociated Cx31 mutants impair the formation of normal gap junctions at different levels, and the diseases associated with Cx31 mutations may result from the abnormal assembly, trafficking and metabolism of the Cx31 mutants.     

Six X-linked agammaglobulinemia-causing missense mutations in the Src homology 2 domain of Bruton's tyrosine kinase: phosphotyrosine-binding and circular dichroism analysis

Src homology 2 (SH2) domains recognize phosphotyrosine (pY)-containing sequences and thereby mediate their association to ligands. Bruton's tyrosine kinase (Btk) is a cytoplasmic protein tyrosine kinase, in which mutations cause a hereditary immunodeficiency disease, X-linked agammaglobulinemia (XLA). Mutations have been found in all Btk domains, including SH2. We have analyzed the structural and functional effects of six disease-related amino acid substitutions in the SH2 domain: G302E, R307G, Y334S, L358F, Y361C, and H362Q. Also, we present a novel Btk SH2 missense mutation, H362R, leading to classical XLA. Based on circular dichroism analysis, the conformation of five of the XLA mutants studied differs from the native Btk SH2 domain, while mutant R307G is structurally identical. The binding of XLA mutation-containing SH2 domains to pY-Sepharose was reduced, varying between 1 and 13% of that for the native SH2 domain. The solubility of all the mutated proteins was remarkably reduced. SH2 domain mutations were divided into three categories: 1) Functional mutations, which affect residues presumably participating directly in pY binding (R307G); 2) structural mutations that, via conformational change, not only impair pY binding, but severely derange the structure of the SH2 domain and possibly interfere with the overall conformation of the Btk molecule (G302E, Y334S, L358F, and H362Q); and 3) structural-functional mutations, which contain features from both categories above (Y361C).     

Mutants of human αB-crystallin cause enhanced protein aggregation and apoptosis in mammalian cells: Influence of co-expression of HspB1

Mutations of human αB-crystallin cause congenital cataract and cardio-myopathy by protein aggregation and cell death. How mutations of αB-crystallin become pathogenic is poorly understood. To better understand the cellular events related to protein aggregation and cell death, we transfected cataract and cardio-myopathy causing mutants, R11H, P20S, R56W, D109H, R120G, D140N, G154S, R157H and A171T in HeLa cells and assessed protein aggregation and apoptosis by laser scanning confocal microspy (LSCM) and flow cytometry. Cells individually transfected with the mutants, D109H, R120G, D140N and R157H significantly showed more aggregates. Cells overexpressed with HspB1 (Hsp27) significantly sequestered aggregates in all mutants and suppressed apoptosis in mutants, P20S, D109H and A171T. Significant increases of apoptotic cells as stained with Annexin V were observed in mutants, D109H and A171T transfected cells. Cells positive for active caspase-3 was increased in the mutant, D109H. Thus the previously recognized anti-apoptotic functions of αB-crystallin were compromised in these mutants.     

Functional consequences of the RNase H2A subunit mutations that cause Aicardi-Goutieres syndrome

Mutations in the three genes encoding the heterotrimeric RNase H2 complex cause Aicardi-Goutières Syndrome (AGS). Our mouse RNase H2 structure revealed that the catalytic RNase H2A subunit interfaces mostly with the RNase H2C subunit that is intricately interwoven with the RNase H2B subunit. We mapped the positions of AGS-causing RNase H2A mutations using the mouse RNase H2 structure and proposed that these mutations cause varied effects on catalytic potential. To determine the functional consequences of these mutations, heterotrimeric human RNase H2 complexes containing the RNase H2A subunit mutations were prepared, and catalytic efficiencies and nucleic acid binding properties were compared with the wild-type (WT) complex. These analyses reveal a dramatic range of effects with mutations at conserved positions G37S, R186W, and R235Q, reducing enzymatic activities and substrate binding affinities by as much as a 1000-fold, whereas mutations at non-conserved positions R108W, N212I, F230L, T240M, and R291H reduced activities and binding modestly or not at all. All mutants purify as three-subunit complexes, further supporting the required heterotrimeric structure in eukaryotic RNase H2. These kinetic properties reveal varied functional consequences of AGS-causing mutations in the catalytic RNase H2A subunit and reflect the complex mechanisms of nuclease dysfunction that include catalytic deficiencies and altered protein-nucleic acid interactions relevant in AGS.