Analysis and stability of Zymomonas mobilis ATCC 10988 plasmid pZMO3

Plasmid pZMO3 of Zymomonas mobilis strain ATCC 10988 was found to be nonhomologous either to chromosomal DNA or to any other plasmids of the strains ATCC 10988, NCIB 11163, and CP4. It contained single sites for the restriction endonucleases SphI, BglI, and HindIII, as well as at least four sites for Sau3A. Its origin of replication is located within the 1.54-kb Sau3A fragment as it was found that only the recombinant plasmid pDS3154, which contained this fragment, showed vectorial incompatibility with the native pZMO3 plasmid. The stability of pZMO3 may be controlled by partitioning sequences located in the 0.64-kb Sau3A fragment. Z. mobilis isolates, which had lost plasmid pZMO3, were successfully isolated.     

Characterization and replication properties of the Zymomonas mobilis ATCC 10988 plasmids pZMO1 and pZMO2

The complete nucleotide sequences of two small cryptic Zymomonas mobilis ATCC 10988 plasmids (pZMO1 and pZMO2) were determined. The plasmids showed 67% homology to each other at their nucleotide level. Plasmid pZMO1 was 1651 bp long with 38% G + C content and contained an open reading frame (ORFZMO1) of 1044 nucleotides. ORFZMO1 is predicted to encode a polypeptide of 348 amino acids and shows a high degree of homology with gram-negative replication proteins of rolling circle replicating plasmids, which belong to the pC194/pUB110 family. Plasmid pZMO2 was found to be 1669 bp long, with a 38.5% G + C content, and it contained an ORF of 552 nucleotides (ORFZMO2) encoding a putative polypeptide of 184 amino acids. This polypeptide also shows a high degree of homology with the replication proteins of RCR plasmids of gram-negative bacteria, but only at their N-termini. The region necessary for replication of both plasmids was determined by stability tests under nonselective conditions, following cloning in pBR325 and introduction in Z. mobilis ATCC 10988 by pRK2013 assisted conjugation. Double- and single-strand origin regions were predicted by sequence analysis. Detection of single-stranded DNA in the extract of exponentially growing cells confirmed experimentally the rolling circle replication mode of at least pZMO2.     

Relative efficacy of different cropping sequences integrated with ploughing for the management of plant parasitic nematodes: Relative wirksamkeit verschiedener beim pflügen integrierter fruchtfolgen zur bekämpfung von pflanzenparasitären nematoden

The relative efficacy of 25 different cropping sequences was tested at the end of the experiment. It appears that for Hoplolaimus indicus sequence number 16, 20, 8 and 10 gave high reduction in rate of reproduction, for Helicotylenchus indicus sequence No. 6, 11, 17 and 3, for Rotylenchulus reniformis sequence No. 2, 8, 13 and 14, for Tylenchorhynchus brassicae sequence No. 6, 24, 3 and 13, for Meloidogyne incognita larvae sequence No. 1, 2, 4 and 24, for Pratylenchus coffeae sequence No. 1, 2, 3 and 5; for Tylenchus filiformis sequence No. 2, 3, 4 and 5.     

A memory-efficient dynamic programming algorithm for optimal alignment of a sequence to an RNA secondary structure

Background  

Covariance models (CMs) are probabilistic models of RNA secondary structure, analogous to profile hidden Markov models of linear sequence. The dynamic programming algorithm for aligning a CM to an RNA sequence of length N is O(N ³) in memory. This is only practical for small RNAs.     

Characterisation of the beta-tubulin gene of Cylicocyclus nassatus

mRNA and genomic DNA were isolated from adult Cylicocyclus nassatus, and the mRNA was reverse transcribed. The cDNA was PCR amplified using degenerate primers designed according to the alignment of the β-tubulin amino acid sequences of other species. To complete the coding sequence, the 3′ end was amplified with the 3′-RACE, and for amplification of the 5′ end the SL1-primer was used. The cDNA of the β-tubulin gene of C. nassatus spans 1429 bp and encodes a protein of 448 amino acids. Specific primers were developed from the cDNA sequence to amplify the genomic DNA sequence and to analyse the genomic organisation of the β-tubulin gene. The complete sequence of the genomic DNA of the β-tubulin gene of C. nassatus has a size of 2652 bp and is organised into nine exons and eight introns. The identities with the exons of the gru-1 β-tubulin gene of Haemonchus contortus range between 79% and 97%.     

Secretory expression of interferon-alpha 2b in recombinant Pichia pastoris using three different secretion signals

Human interferon-alpha 2b (IFN-α2b) was cloned and expressed in Pichia pastoris under the control of alcohol oxidase promoter (AOX1) using three different secretion signals. Native secretion signal of IFN-α2b, Saccharomyces cerevisiae MF-α factor prepro sequence and a mutated α prepro sequence without the Glu-Ala (EAEA) repeats were used separately for directing the secretion of IFN-α2b into the culture medium of P. pastoris. The native secretion signal of IFN-α2b did not secrete protein into the culture medium of P. pastoris. The α prepro sequence without the EAEA repeats directed the secretion of maximum amount of IFN-α2b (200 mg/l) into the culture medium, with the same amino acid sequence as that of the native IFN-α2b secreted by human lymphocytes. The full α prepro sequence, having both the protease cleavage sites for KEX2 and STE13 gene products, also secreted an equivalent amount of IFN-α2b into the culture medium. However, two interferon bands with similar molecular masses were observed, when full α prepro sequence was used for the secretion of IFN-α2b. The difference in the molecular masses of the two bands was found to arise due to the difference in the molecular masses of the N-terminal fragment, and the inefficient processing of secretion signal.     

Characterization of Three Novel Human Cadherin Genes (CDH7, CDH19, and CDH20) Clustered on Chromosome 18q22–q23 and with High Homology to Chicken Cadherin-7

Full-length coding sequences of two novel human cadherin cDNAs were obtained by sequence analysis of several EST clones and 5′ and 3′ rapid amplification of cDNA ends (RACE) products. Exons for a third cDNA sequence were identified in a public-domain human genomic sequence, and the coding sequence was completed by 3′ RACE. One of the sequences (CDH7L1, HGMW-approved gene symbol CDH7) is so similar to chicken cadherin-7 gene that we consider it to be the human orthologue. In contrast, the published partial sequence of human cadherin-7 is identical to our second cadherin sequence (CDH7L2), for which we propose CDH19 as the new name. The third sequence (CDH7L3, HGMW-approved gene symbol CDH20) is almost identical to the mouse “cadherin-7” cDNA. According to phylogenetic analysis, this mouse cadherin-7 and its here presented human homologue are most likely the orthologues of Xenopus F-cadherin. These novel human genes, CDH7, CDH19, and CDH20, are localized on chromosome 18q22–q23, distal of both the gene CDH2 (18q11) encoding N-cadherin and the locus of the six desmosomal cadherin genes (18q12). Based on genetic linkage maps, this genomic region is close to the region to which Paget's disease was linked. Interestingly, the expression patterns of these three closely related cadherins are strikingly different.     

Genetic Mapping of a Possible New Alcohol Dehydrogenase Sequence to Mouse Chromosome 3 at the Adh-1/Adh-3 Complex

Southern blot analysis of mouse genomic DNA reveals two Eco RI fragments which faintly hybridize to mouse Adh-1 cDNA and are not part of the Adh-1 gene. These fragments were isolated from agarose gels, cloned, and characterized. Sequence analysis of the 2.1-kb Eco RI fragment suggests that it is likely a pseudogene since it does not contain a long open reading frame. However, the 2.0-kb Eco RI fragment contains a coding sequence with a long open reading frame which corresponds to exon 6 of the mouse Adh-1 gene. Comparison of the coding sequence with other known ADHs suggests that the sequence has diverged sufficiently from any currently known class of ADH to be a possible distinct class. Further confirmation awaits analysis of currently available genomic clones. Using these sequences as probe, restriction fragment length polymorphisms were identified for each sequence between C57Bl/6J and DBA/2J inbred mouse strains. The strain distribution pattern for these allelic differences was determined among the B × D recombinant inbred strains. This analysis revealed that the 2.1-kb Eco RI sequence is located on chromosome 3 but at a distance from the Adh-1/Adh-3 complex as previously reported. However, the new polymorphism identified in the 2.0-kb Eco RI fragment enabled this sequence to be mapped at the Adh-1/Adh-3 complex.     

玉米胚胎发生后期丰富蛋白基因的启动子克隆与功能验证

该研究在生物信息学分析的基础上,克隆玉米胚胎发生后期丰富蛋白基因(MGL3)的启动子序列(pMGL3),进行非生物逆境应答元件分析以及实时定量PCR验证其非生物逆境胁迫响应特性,构建了pMGL3启动子驱动报告基因(GUS)表达载体,基因枪法转化玉米愈伤组织,通过GUS染色验证pMGL3启动子在非生物逆境胁迫下的驱动活性。再根据启动子序列分析结果,去除不同的顺式作用元件,构建不同长度pMGL3启动子驱动报告基因GUS表达载体,农杆菌介导法转化烟草叶盘,以确定pMGL3启动子的最短活性序列。结果显示:pMGL3启动子长1 554bp,存在多种与非生物逆境胁迫应答相关的调控元件,在干旱、高盐、低温胁迫及脱落酸、乙烯诱导下驱动MGL3基因增量表达,用以驱动GUS基因转化玉米愈伤组织,在高渗、高盐、低温胁迫及脱落酸诱导下具有驱动活性,且截短至325bp仍可保持驱动活性。研究表明,pMGL3启动子的确有非生物逆境诱导启动活性,进一步验证其作用机理后可运用于玉米抗逆转基因研究。     

The Saccharomyces cerevisiae MET3 gene: nucleotide sequence and relationship of the 5'' non-coding region to that of MET25

Summary In Saccharomyces cerevisiae, the expression of several genes implicated in methionine biosynthesis is coregulated by a specific negative control. To elucidate the molecular basis of this regulation, we have cloned two of these genes, MET3 and MET25. The sequence of MET25 has already been determined (Kerjan et al. 1986). Here, we report the nucleotide sequence of the MET3 gene along with its 5 and 3 flanking regions. Plasmids bearing different deletions upstream of the transcribed region of MET3 were constructed. They were introduced into yeast cells and tested for their ability to complement met3 mutations and to respond to regulation by exogenous methionine. The regulatory region was located within a 100 bp region. The sequence of this regulatory region was compared with that of MET25. A short common sequence which occurs 250–280 bp upstream of the translation initiation codon of the gene was found. This sequence is a good candidate for the cis-acting regulatory element.     

Mapping sequences by parts

Background:  

We present the N-map method, a pairwise and asymmetrical approach which allows us to compare sequences by taking into account evolutionary events that produce shuffled, reversed or repeated elements. Basically, the optimal N-map of a sequence s over a sequence t is the best way of partitioning the first sequence into N parts and placing them, possibly complementary reversed, over the second sequence in order to maximize the sum of their gapless alignment scores.     

<Emphasis Type="Italic">In Silico</Emphasis> sequence analysis and molecular modeling of the three-dimensional structure of DAHP synthase from <Emphasis Type="Italic">Pseudomonas fragi</Emphasis>

The shikimate pathway is involved in production of aromatic amino acids in microorganisms and plants. The enzymes of this biosynthetic pathway are a potential target for the design of antimicrobial compounds and herbicides. 3-deoxy-D-arabinoheptulosonate-7-phosphate synthase (DAHPS) catalyzes the first step of the pathway. The gene encoding DAHPS was cloned and sequenced from Pseudomonas fragi, the bacterium responsible for spoilage of milk, dairy products and meat. Amino acid sequence deduced from the nucleotide sequence revealed that P. fragi DAHPS (Pf-DAHPS) consists of 448 amino acids with calculated molecular weight of ∼50 kDa and isoelectric point of 5.81. Primary sequence analysis of Pf-DAHPS shows that it has more than 84% identity with DAHPS of other Pseudomonas species, 46% identity with Mycobacterium tuberculosis DAHPS (Mt-DAHPS), the type II DAHPS and less than 11% sequence identity with the type I DAHPS. The three-dimensional structure of Pf-DAHPS was predicted by homology modeling based on the crystal structure of Mt-DAHPS. Pf-DAHPS model contains a (β/α)₈ TIM barrel structure. Sequence alignment, phylogenetic analysis and 3D structure model classifies Pf-DAHPS as a type II DAHPS. Sequence analysis revealed the presence of DAHPS signature motif DxxHxN in Pf-DAHPS. Highly conserved sequence motif RxxxxxxKPRT(S/T) and xGxR present in type II DAHPS were also identified in Pf-DAHPS sequence. High sequence homology of DAHPS within Pseudomonas species points to the option of designing a broad spectrum drug for the genus. Pf-DAHPS 3D model provides molecular insights that may be beneficial in rationale inhibitor design for developing effective food preservative against P. fragi.     

Allelic diversity at the primateMhc-G locus: Exon 3 bears stop codons in allCercophitecinae sequences

Twenty-seven major histocompatibility complex (Mhc)-G exon 2, exon 3, and exon 2 and 3 allelic sequences were obtained together with 12 different intron 2 sequences.Homo sapiens, Pan troglodytes, Pan paniscus, Gorilla gorilla, Pongo pygmaeus, Macaca fascicularis, Macaca mulatta, andCercopithecus aethiops individuals were studied. Polymorphism does not follow the classical pattern of three hypervariable regions per domain and is found in all species studied; exon 3 (equivalent to the 2 protein domain) shows stop codons in theCercopithecinae group but not in thePongidae and human groups. Dendrograms show that cotton top tamarin (Saguinus oedipus) Mhc-G sequences are closer toHomo sapiens andPongidae than toCercopithecinae, probably due to the stop codons existing at exon 3 of the latter. There is a clear trans-species evolution of allelism inCercopithecinae and also in exon 2 of all the other apes studied, but a generation of allelism within each species may be present on exon 3 sequences. This discrepancy may be due to the preferential use of exon 2 over exon 3 at the mRNA splicing level within each species in order to obtain the appropriate functional G product.Mhc-G intron 2 shows conserved motifs in all species studied, particularly a 23 base pair deletion between positions 161 and 183 which is locus specific, and some of the invariant residues, important for peptide presentation, conserved in classical class 1 molecules from fish and reptiles to humans were not found inMhc-G alleles; the intron 2 Dendrogram also shows a particular pattern of allelism within each species. In summary,Mhc-G has substantial differences from other classical class I genes: polymorphism patterns, tissue distribution, gene structure, splicing variability, and probably an allelism variability within each species at exon 3. The G proteins may also be different. This indicates that theMhc-G function may not be peptide presentation to the clonotypic T-cell receptor.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence data base and have been assigned the accession numbers L41362 (HLA-G*01012), L41363 (HLA-G*01013), U33307 (intron 2HLA-G sequence from BeWo cell line), L48999 (Patr-Mhc-G*I), U33291 [Patr Mhc-G*II(3)], L49003 (intron 2Patr Mhc-G*I sequence), L48998 (Gogo Mhc-G*I), L49002 (intron 2Gogo Mhc-G*I sequence), L49000 (Popy Mhc-G*I), L49001 (Popy Mhc-G*II), L49004 (intron 2Popy Mhc-G*I sequence), L49005 (intron 2Popy Mhc-G*II sequence), U33312 (Mafa Mhc-G*I), U33301 (Mafa Mhc-G*II), U33302 (Mafa Mhc-G*III), U33303 (Mafa Mhc-G*IV), L41257 [Mafa Mhc-G*V(3)], L41259 [Mafa Mhc-G*VI(3)], L41260 [Mafa Mhc-G*VII(3)], U33296 (intron 2Mafa Mhc-G*I/*II/*III sequence), U33297 (intron 2Mafa Mhc-G*IV sequence), U33304 (Mamu Mhc-G*I), U33305 (Mamu Mhc-G*II), U33306 (Mamu Mhc-G*III), U33295 (Mamu Mhc-G*IV), L41263 [Mamu Mhc-G*V(3)], L41261 [Mamu Mhc-G*VI(3)], L41264 [Mamu Mhc-G*VII(3)], U33298 (intron 2Mamu Mhc-G*I/III sequence), U33299 (intron 2Mamu Mhc-G*II sequence), U33300 (intron 2Mamu Mhc-G*IV sequence), U33310 (Ceae Mhc-G*I), U33311 (Ceae Mhc-G*II), U33308 (intron 2Ceae Mhc-G*I sequence), and U33309 (intron 2Ceae Mhc-G*II)The contribution by M.J. Castro and P. Morales is equal and the order of authorship is arbitrary     

Structure,diversity and evolutionary patterns of expressed MHC class II<Emphasis Type="Italic">B</Emphasis> genes in chub (<Emphasis Type="Italic">Squalius cephalus</Emphasis>), a cyprinid fish species from Europe

The polymorphism of exon 2 of the DAB genes (major histocompatibility complex [MHC] class IIB) was investigated for the first time in the freshwater cyprinid fish species, Squalius cephalus, in the wide range of its distribution in Europe. We identified 111 different MHC class IIB variants in 15 chub populations distributed from Finland to Spain. The sequence analysis showed that many structurally important amino acid sites that were conserved among tetrapods were also conserved in chub. The analysis of recombination indicated that it does not play an important role in producing and maintaining the variation of DAB genes analyzed in the present study. The exon 2 was shown to be subjected to intense positive selection. Phylogenetic analysis and sequence identities suggest the presence of two class IIB loci (DAB1-like and DAB3-like) in chub. Nevertheless, the presence of three DAB3-like sequence variants in several individuals indicates the duplication of the DAB3 gene. A contrasting selection pattern was found in DAB1-like and DAB3-like genes, which suggests the potential functional differences between these genes. Some DAB sequence variants were shared among the populations of different mtDNA lineages. The phylogenetic analyses did not confirm any biogeographical pattern of the genetic structure of MHC IIB in chub, which is in line with balancing selection and trans-species polymorphism in MHC genes. Nevertheless, cluster analysis based on the presence/absence of DAB sequence variants in the populations showed the phylogeophraphical pattern corresponding to the mtDNA lineages, which indicates that neutral selection can partially explain the MHC IIB evolution in chub.     

The Autonomously Replicating Sequence (ARS) of the Yeast Saccharomyces exiguus Yp74L-3

Fragments containing ARSes were cloned from the genomic DNA of the yeast Saccharomyces exiguus Yp74L-3, and the essential regions for ARSes were restricted for these fragments. Mapping studies of ARS-acting sequences in one of these fragments suggested that S. exiguus recognizes a sequence as an ARS that is different from that recognized by Saccharomyces cerevisiae. Two ARS essential regions of S. exiguus were sequenced, and an ARS core consensus sequence of S. exiguus was deduced to be MATTAMWAWWTK. This sequence differs significantly from that of S. cerevisiae in two positions, suggesting that these nucleotide substitutions cause the difference in the ARS-recognition modes between S. exiguus and S. cerevisiae. Received: 3 August 1998 / Accepted: 18 September 1998