Loss-of-function mutations in RAB18 cause Warburg micro syndrome

Warburg Micro syndrome and Martsolf syndrome are heterogenous autosomal-recessive developmental disorders characterized by brain, eye, and endocrine abnormalities. Previously, identification of mutations in RAB3GAP1 and RAB3GAP2 in both these syndromes implicated dysregulation of the RAB3 cycle (which controls calcium-mediated exocytosis of neurotransmitters and hormones) in disease pathogenesis. RAB3GAP1 and RAB3GAP2 encode the catalytic and noncatalytic subunits of the hetrodimeric enzyme RAB3GAP (RAB3GTPase-activating protein), a key regulator of the RAB3 cycle. We performed autozygosity mapping in five consanguineous families without RAB3GAP1/2 mutations and identified loss-of-function mutations in RAB18. A c.71T > A (p.Leu24Gln) founder mutation was identified in four Pakistani families, and a homozygous exon 2 deletion (predicted to result in a frameshift) was found in the fifth family. A single family whose members were compound heterozygotes for an anti-termination mutation of the stop codon c.619T > C (p.X207QextX20) and an inframe arginine deletion c.277_279 del (p.Arg93 del) were identified after direct gene sequencing and multiplex ligation-dependent probe amplification (MLPA) of a further 58 families. Nucleotide binding assays for RAB18(Leu24Gln) and RAB18(Arg93del) showed that these mutant proteins were functionally null in that they were unable to bind guanine. The clinical features of Warburg Micro syndrome patients with RAB3GAP1 or RAB3GAP2 mutations and RAB18 mutations are indistinguishable, although the role of RAB18 in trafficking is still emerging, and it has not been linked previously to the RAB3 pathway. Knockdown of rab18 in zebrafish suggests that it might have a conserved developmental role. Our findings imply that RAB18 has a critical role in human brain and eye development and neurodegeneration.     

Localization of the Escherichia coli rnt gene encoding RNase T by using a combination of physical and genetic mapping.

The rnt gene encoding RNase T was cloned on a 13-kilobase BamHI fragment. Restriction analysis of the fragment and comparison of it with the Escherichia coli restriction map localized rnt to kilobase coordinates 1733 to 1746, corresponding to about 36 min on the genetic map. The map location was confirmed by cotransduction with the nearby zdg-229::Tn10 and ksgB1 markers.     

Mycoplasma hyopneumoniae Surface proteins Mhp385 and Mhp384 bind host cilia and glycosaminoglycans and are endoproteolytically processed by proteases that recognize different cleavage motifs

P97 and P102 paralogues occur as endoproteolytic cleavage fragments on the surface of Mycoplasma hyopneumoniae that bind glycosaminoglycans, plasminogen, and fibronectin and perform essential roles in colonization of ciliated epithelia. We show that the P102 paralogue Mhp384 is efficiently cleaved at an S/T-X-F↓X-D/E-like site, creating P60(384) and P50(384). The P97 paralogue Mhp385 is inefficiently cleaved, with tryptic peptides from a 115 kDa protein (P115(385)) and 88 kDa (P88(385)) and 27 kDa (P27(385)) cleavage fragments identified by LC-MS/MS. This is the first time a preprotein belonging to the P97 and P102 paralogue families has been identified by mass spectrometry. The semitryptic peptide (752)IQFELEPISLNV(763) denotes the C-terminus of P88(385) and defines the novel cleavage site (761)L-N-V↓A-V-S(766) in Mhp385. P115(385), P88(385), P27(385), P60(384), and P50(384) were shown to reside extracellularly, though it is unknown how the fragments remain attached to the cell surface. Heparin- and cilium-binding sites were identified within P60(384), P50(384), and P88(385). No primary function was attributed to P27(385); however, this molecule contains four tandem R1 repeats with similarity to porcine collagen type VI (α3 chain). P97 and P102 paralogue families are adhesins targeted by several proteases with different cleavage efficiencies, and this process generates combinatorial complexity on the surface of M. hyopneumoniae.     

The enteropathogenic Escherichia coli type III secretion system effector Map binds EBP50/NHERF1: implication for cell signalling and diarrhoea

Enteropathogenic Escherichia coli (EPEC) is the single most important contributor to child diarrhoea in developing countries. Nevertheless, the mechanism responsible for EPEC diarrhoea remains elusive. Using the yeast two-hybrid system to determine the target host cell protein of the EPEC type III secretion system effector Map led to identification of ezrin/radixin/moesin (ERM)-binding phosphoprotein 50 (EBP50), also known as Na+/H+ exchanger regulatory factor 1 (NHERF1). Protein interaction is mediated by the carboxy-terminal Thr-Arg-Leu (TRL) motif of Map and the PSD-95/Disk-large/ZO-1 domain 1 (PDZ1) of EBP50/NHERF1. Although EBP50/NHERF1 is recruited to site of EPEC adhesion in a Map-independent mechanism, co-immunoprecipitation and immunostaining revealed that Map binds to, induces proteolysis of, and colocalizes with EBP50/NHERF1 during infection of cultured epithelial cells. The TRL motif of Map was involved in Map-induced filopodia formation and brush border elongation on infected HeLa and Caco-2 cells respectively. As EBP50/NHERF1 regulates ion channels in the intestine we assessed the involvement of Map in diarrhoea using the Citrobacter rodentium mouse model of EPEC. We report significantly greater diarrhoea following infections with wild-type C. rodentium compared with C. rodentiumDeltamap. These results provide new insights into the mechanisms of EPEC diarrhoea.     

A basic NH2-terminal extension of rat liver arginyl-tRNA synthetase required for its association with high molecular weight complexes

Rat liver arginyl-tRNA synthetase is found in extracts either as a component (Mr = 72,000) of a high molecular weight aminoacyl-tRNA synthetase complex or as a low molecular weight (Mr = 60,000) free form. Previous studies suggested that the free protein arises from the complex-derived form by a limited proteolysis that removes the portion of the protein required for its association with the complex. In order to determine the location in the protein and some structural properties of this extra 12-kDa portion, the complex-derived and free forms were each extensively purified and compared by peptide mapping using limited V-8 protease digestion. The two proteins showed 7-8 peptide bands in common, as well as 1-2 unique bands each. Treatment of each of the proteins with carboxypeptidase Y prior to digestion with V-8 protease indicated that the two proteins have a common COOH-terminal peptide. Amino acid analyses of the two arginyl-tRNA synthetases revealed a strong similarity; however, the complex-derived form contained a large excess of basic amino acids. These results demonstrate directly that the complex-derived and free forms of arginyl-tRNA synthetase are closely related proteins, but that the former includes a basic, NH2-terminal extension absent in the free form. The role of this extra segment in the polyanion-binding properties of eukaryotic synthetases and in their structural organization into high molecular weight complexes is discussed.     

Escherichia coli RNase D: sequencing of the rnd structural gene and purification of the overexpressed protein.

We have determined the nucleotide sequence of a 1.4-kb-pair fragment of the E. coli chromosome that carries the complete rnd gene encoding RNase D, a putative tRNA processing enzyme. The coding region of rnd extends for a total of 1128 nucleotides beginning at an initiator UUG codon and terminating at a UAA codon, and encodes a 375-amino acid polypeptide of 42,679 daltons, consistent with the known size of RNase D. A rapid purification procedure was developed for isolation of RNase D from strains overexpressing the enzyme. The N-terminal sequence and the amino acid composition of the homogenous protein were in excellent agreement with those derived from the sequence of the rnd gene.