The plant mitochondrial open reading frame orf221 encodes a membrane-bound protein

We have shown that the open reading frame orf221 is an active mitochondrial gene which encodes a novel mitochondrial polypeptide. The orf221 sequence is common to higher plants but absent in animal and fungal mitochondria. A mitochondrial polypeptide with an apparent molecular weight of 21 000 was detected with a polyclonal antibody raised against an ORF221 fusion protein. In organello translation followed by immunoprecipitation with the anti-ORF221 antibody demonstrated that this polypeptide is encoded by the orf221 gene in plant mitochondria. The ORF221 was found to be a mitochondrial membrane protein in normal (N), cms-T, and cms-C cytoplasms of several inbred lines of maize (Zea mays L.) and in other plant species.     

Characterization of the wheat mitochondrial orf25 gene

The wheat mitochondrial orf25 nucleotide sequence of 576 pb has been determined. Its derived protein sequence shares 88% and 75% amino acid identity with those of maize and tobacco mitochondria, respectively. The wheat and tobacco orf25 sequences lack four inserts, of 6 bp to 36 bp, that are present in the maize homologue. The wheat orf25 gene is actively transcribed and is preceded by a regulatory sequence block very similar to those located upstream of the wheat coxII and atp6 genes. Our observations support the view that orf25 sequences encode a functional polypeptide in plant mitochondria.     

Proximity of the poly(A)-binding protein to a premature termination codon inhibits mammalian nonsense-mediated mRNA decay

mRNA surveillance pathways selectively clear defective mRNAs from the cell. As such, these pathways serve as important modifiers of genetic disorders. Nonsense-mediated decay (NMD), the most intensively studied surveillance pathway, recognizes mRNAs with premature termination codons (PTCs). In mammalian systems the location of a PTC more than 50 nucleotides 5' to the terminal exon-exon junction is a critical determinant of NMD. However, mRNAs with nonsense codons that fulfill this requirement but are located very early in the open reading frame can effectively evade NMD. The unexpected resistance of such mRNAs with AUG-proximal PTCs to accelerated decay suggests that important determinants of NMD remain to be identified. Here, we report that an NMD-sensitive mRNA can be stabilized by artificially tethering the cytoplasmic poly(A) binding protein 1, PABPC1, at a PTC-proximal position. Remarkably, the data further suggest that NMD of an mRNA with an AUG-proximal PTC can also be repressed by PABPC1, which might be brought into proximity with the PTC during cap-dependent translation and 43S scanning. These results reveal a novel parameter of NMD in mammalian cells that can account for the stability of mRNAs with AUG-proximal PTCs. These findings serve to expand current mechanistic models of NMD and mRNA translation.     

Plasmodium falciparum: enhanced soluble expression, purification and biochemical characterization of lactate dehydrogenase

Plasmodium lactate dehydrogenase (pLDH), owing to unique structural and kinetic properties, is a well known target for antimalarial compounds. To explore a new approach for high level soluble expression of Plasmodium falciparum lactate dehydrogenase (PfLDH) in E. coli, PfLDH encoding sequence was cloned into pQE-30 Xa vector. When transformed E. coli SG13009 cells were induced at 37 °C with 0.5 mM isopropyl β-d-thiogalactoside (IPTG) concentration, the protein was found to be exclusively associated with inclusion bodies. By reducing cell growth temperature to 15 °C and IPTG concentration to 0.25 mM, it was possible to get approximately 82% of expressed protein in soluble form. Recombinant PfLDH (rPfLDH) was purified to homogeneity yielding 18 mg of protein/litre culture. rPfLDH was found to be biologically active with specific activity of 453.8 μmol/min/mg. The enzyme exhibited characteristic reduced substrate inhibition and enhanced k_cat [(3.2 ± 0.02) × 10⁴] with 3-acetylpyridine adenine dinucleotide (APAD⁺). The procedure described in this study may provide a reliable and simple method for production of large quantities of soluble and biologically active PfLDH.     

L1-ORF2不同片段对报告基因表达产生不同影响

长散布重复序列-1(Line-1, L1)是重要的人类基因组成分, 完整的L1有6 kb, 在基因组中存在的L1多数是不完整序列, 有必要研究L1片段对基因表达的调控作用。PCR扩增L1第二读码框(L1-ORF2)不同位置的 280 bp片段, 共7段, 同向8串联按正、反方向分别插入pEGFP质粒GFP基因下游, 观察插入序列对GFP报告基因表达的影响。构建的质粒瞬时转染HeLa细胞, 经荧光显微镜和Northern检测, 不同片段对转录量和终止影响不同。7个片段正序对GFP报告基因的抑制均高于其反序, 在正序串联表达载体p280-1*8和p280-9*8的GFP基因转录量超过其他280正序插入片段, 在反序串联表达载体p280-1*8as和p280-9*8as的GFP基因转录量超过其他280反序片段。280-1*8、280-9*8、280-1*8as和280-9*8as属于转录终止性序列。Alu在基因组的多数区段与L1分布呈反比, Alu正、反序均对GFP表达有抑制作用, 但反序抑制作用高于正序, Alu正序属于转录延伸性序列。280 bp片段反序插入的所有质粒荧光阳性细胞均高于正序插入质粒。经碱基分析, L1-ORF2各段均存在A碱基含量多, T碱基含量少的现象, 这可能是其正、反序对基因表达影响不同的原因。     

Restriction endonuclease inhibitor IPI* of bacteriophage T4: a novel structure for a dedicated target

Phage T4 protects its DNA from the two-gene-encoded gmrS/gmrD (glucose-modified hydroxymethylcytosine restriction endonuclease) CT of pathogenic Escherichia coli, CT596, by injecting several hundred copies of the 76-amino-acid-residue nuclease inhibitor, IPI*, into the infected host. Here, the three-dimensional solution structure of mature IPI* is reported as determined by nuclear magnetic resonance techniques using 1290 experimental nuclear Overhauser effect and dipolar coupling constraints (∼ 17 constraints per residue). Close examination of this oblate-shaped protein structure reveals a novel fold consisting of two small β-sheets (β1: B1 and B2; β2: B3-B5) flanked at the N- and C-termini by α-helices (H1 and H2). Such a fold is very compact in shape and allows ejection of IPI* through the narrow 30-Å portal and tail tube apertures of the virion without unfolding. Structural and dynamic measurements identify an exposed hydrophobic knob that is a putative gmrS/gmrD-binding site. A single gene from the uropathogenic E. coli UT189, which codes for a gmrS/gmrD-like UT fusion enzyme (with ∼ 90% identity to the heterodimeric CT enzyme), has evolved IPI* inhibitor immunity. Analysis of the gmrS/gmrD restriction endonuclease enzyme family and its IPI* family phage antagonists reveals an evolutionary pathway that has elaborated a surprisingly diverse and specifically fitted set of coevolving attack and defense structures.