Identification of the gene(s) coding for the trans-sialidase of Trypanosoma cruzi.

The gene(s) encoding the Trypanosoma cruzi shed-acute-phase-antigen (SAPA) has a 5' end encoding a region containing two totally and two partially conserved Ser-X-Asp-X-Gly-X-Thr-Trp motifs which are present in bacterial neuraminidases, and a 3' end encoding tandemly repeated units of 12 amino acids. It is now reported that 54-87% of the total neuraminidase activity present in the parasite could be immunoprecipitated with polyclonal or monoclonal antibodies against the repeated amino acid units of SAPA. These immunoprecipitates also had greater than 80% of the trans-sialidase activity of the parasite. SAPA used sialyllactose, fetuin and 4-methylumbelliferyl-sialic acid as substrate donors. In the presence of a suitable acceptor molecule (lactose) the sialic acid residues were transferred to the disaccharide, whereas in the absence of acceptors the residues were transferred to water. If relatively inefficient acceptors (maltose or cellobiose) were added to the incubation mixtures, the sialic acid units were transferred both to the disaccharides and to water. It is concluded that a major T. cruzi antigen has both the trans-sialidase and the neuraminidase activities of the parasite. Both activities are probably located on the N-terminus of SAPA since antibodies directed against the C-terminus, which contains the repeated amino acid units, do not affect the enzymatic activities.     

Correlation between AgNOR count and subjective AgNOR pattern assessment score in cytology and histology of breast lumps.

OBJECTIVE: To find the correlation of argyrophilic nucleolar organizer region (AgNOR) count and subjective AgNOR pattern assessment (SAPA) score in cytology and histology of breast lumps. STUDY DESIGN: The study group consisted of 73 patients (46 malignant, 27 benign) with breast lumps. In all cases, fine needle aspiration cytology (FNAC) samples and histologic specimens were studied by conventional and silver staining for AgNORs. RESULTS: AgNOR count and SAPA score were helpful in differentiating benign from malignant tumors in both the cytologic smear and histologic specimen. AgNOR count was 6.94+/-2.74 in FNAC and 6.57+/-2.73 in histology of malignant tumors, while in benign tumors it was 2.75+/-0.74 in FNAC and 2.68+/-0.77 in histology. SAPA score was 9.02+/-4.60 in FNAC and 8.76+/-2.34 in histology in malignant tumors and 5.87+/-0.93 in FNAC and 5.82+/- 0.83 in histology in benign tumors. CONCLUSION: Both AgNOR count and SAPA score gave similar results, but SAPA score is a more convenient, reproducible and rapid method of AgNOR evaluation.     

Characterization of two types of rRNA gene repeat units from the crustacean Artemia

We have previously described that Artemia rRNA genes are organized with a basic repeat unit of 16.5 kb [Cruces et al., Biochem. Biophys. Res. Commun. 98 (1981) 404-409]. Here we describe the organization of the DNA coding for rRNA of a different population of this crustacean that has a repeat unit of 12.2 kb. Both types of repeat units have been cloned and the organization of the external spacers studied by restriction analysis. Both external spacers contain repeated sequences, but they are not homologous to each other. Sequences from the external spacer of the 16.5 kb repeat are also found elsewhere in the genome, within sequences not related to rRNA genes.     

Unusual ribosomal RNA gene organization in copepods of the genus Calanus

Ribosomal RNA genes in the nuclear genomes of eukaryotes are generally found in tandemly repeated units encoding 18 S, 5.8 S and 28 S rRNA (in that order). 5 S rRNA genes typically lie outside these units, most often in tandem clusters coding exclusively for 5 S rRNA. Inclusion of 5 S genes within the 18 S-5.8 S-28 S repeat unit is known only for certain protozoa and fungi. Here we report that, in the copepod Calanus finmarchicus, single 5 S genes are included within many or all of the 18 S-5.8 S-28 S repeat units. Sequence analyses of regions cloned from two of these repeat units show that they indeed include 5 S genes (which are distal to 28 S genes) and that these are transcribed from opposite strands.     

Sequence arrangement of the rDNA of Drosophila melanogaster.

The sequence arrangement of genes coding for stable rRNA species and of the interspersed spacers on long single strands of rDNA purified from total chromosomal DNA of Drosophila melanogaster has been determined by a study of the structure of rRNA:DNA hybrids which were mounted for electron microscope observation by the gene 32-ethidium bromide technique. One repeat unit contains the following sequences in the order given. First, an 18 S gene of length 2.13 +/- 0.17 kb. Second, an internal transcribed spacer (Spl) of length 1.58 +/- 0.15 kb. A short sequence coding for the 5.8S and perhaps the 2S rRNA species is located within this spacer. Third, the 28S gene with a length of 4.36 +/- 0.23 kb. About 55% of the 28S genes are unbroken or continuous (C genes). However, about 45% of the 28S genes contain an insertion of an additional segment of DNA that is not complementary to rRNA (l genes). The insertion occurs at a reproducible point 2.99 +/- 0.26 kb from the junction with Spl. The insertions are heterogeneous in length and occur in three broad size classes: 1.42 +/- 0.47, 3.97 +/- 0.55, and 6.59 +/- 0.62 kb. Fourth, an external spacer between the 28S gene and the next 18S gene which is presumably mainly nontranscribed and which has a heterogeneous length distribution with a mean length and standard deviation of 5.67 +/- 1.92 kb. Short inverted repeat stems (100-400 nucleotide pairs) occur at the base of the insertion. It is known from other studies that I genes occur only on the X chromosome. The present study shows that the I and C genes on the X chromosomes are approximately randomly assorted. The sequence arrangement on the plasmid pDm103 containing one repeat of rDNA (Glover et al., 1975) has been determined by similar methods. The I gene on this plasmid contains an inverted repeat stem. The occurrence of inverted repeat sequences flanking the insertion supports the speculation that these sequences are translocatable elements similar to procaryotic translocons.     

Restriction mapping of the rRNA genes from Artemia larvae

A restriction endonuclease analysis of the genes coding for the ribosomal RNA from Artemia larvae has shown that these genes consist of a repeat unit of 16.2 kilobase pairs (10.7 Mdaltons) and that the repeat unit seems to be homogeneous in size.     

Fast ECG data compression algorithms suitable for microprocessor systems

ECG data compression techniques have received extensive attention in ECG analysis. Numerous data compression algorithms for ECG signals have been proposed during the last three decades. We describe two algorithms based on the scan-along polygonal approximation algorithm (SAPA) that are suitable for multichannel ECG data reduction on a microprocessor-based system. One represents a modification of SAPA (MSAPA) which adopts the method of integer division table searching to speed up data reduction; the other (CSAPA) combines MSAPA and TP, a turning-point algorithm, to preserve ST segment signals. Results show that our algorithms achieve a compression ratio of more than 5:1 and a percent rms difference (PRD) to the original signal of less than 3.5%. In addition, the maximum execution time of MSAPA for processing one data point is about 50μ s. Moreover, the CSAPA algorithm retains all of the details of the ST segment, which are important in ischaemia diagnosis, by employing the TP algorithm.     

Presence in invertebrate genomes of sequences characterized by the repetition of the triplet CCPurine

In Drosophila melanogaster (Dm), polypeptidic domains have been found in different morphogenetic genes. Two types of them are characterized by the repetition of nucleotidic triplets: the M repeat (CAX) and the paired repeat (CAXCCX). In this paper we described a third type of repeat isolated from the genome of a Polychaete annelid: Owenia fusiformis. This repeat is characterized by the repetition of the triplet CCPurine. Phylogenetic studies showed the presence of this repeat in all the invertebrate genomes tested (eight copies in Dm genome) while we failed to detect it in vertebrate genomes.     

H-DNA formation by the coding repeat elements of neisserial opa genes

The coding repeat region of opa genes from Neisseria gonorrhoeae and Neisseria meningitidis determines the expression state of their respective genes through high-frequency addition of deletion of pentanucleotide coding repeat units (CRs; CTTCT). In vitro analyses of cloned opa gene CR regions using single-strand specific nucleases, oligonucleotide protection experiments, and modifications of non-B-DNA residues indicate that the regions form structures resembling H-DNA under acidic conditions in the presence of negative supercoiling. The purine/pyrimidine strand bias and H-palindromic nature of the repeat region are consistent with sequence requirements for H-DNA formation. Sequences flanking the repeat elements are required to form the H-DNA structure in vitro as judged by the pattern of exposed non-B-DNA residues in CR sequences synthesized as oligonucleotides to form beta-galactosidase::CR translational fusions. The fusions phase vary by addition and deletion of CR elements and the rate of phase variation increases upon induction of the fusion genes. The opa gene CR region is the first reported bacterial H-DNA structure and is unique in that it lies within the coding sequence for the gene.     

The organization of repetitive sequences in a cluster of rabbit β-like globin genes

Several complementary procedures were used to identify and characterize DNA sequences which are repeated within a 44 kilobase (kb) segment of rabbit chromosomal DNA containing four different rabbit β-like globin genes (β1–β4). Cross-hybridization between cloned DNAs from different regions of the gene cluster indicates the presence of a complex array of repeat sequences interspersed with the globin genes. We classified 20 different repeat sequences into five families whose members cross-hybridize. Electron microscopy was used to determine the location, size and relative orientations of many of the repeat sequences. Both direct and inverted repeats were identified, with sizes ranging from 140 to 1400 base pairs (bp). Each of the four closely linked globin genes is flanked by at least one pair of inverted repeats of 140–400 bp, and the entire set of four genes is flanked by an inverted repeat of 1400 bp. Two of the five repeat families contain repeat sequences of different sizes. We found that the smaller sequence elements can occur individually or in association with the larger repeat sequences, suggesting that the larger repeats may be composed of more than one smaller repeat sequence. The restriction fragments containing the intracluster repeats also contain sequences which are repeated many times in total rabbit genomic DNA, but it is not known whether the genomic and intracluster repeats are the same sequences. The results provide the first demonstration of the relationship between single-copy and repetitive DNA sequences in a large segment of chromosomal DNA containing a well characterized set of developmentally regulated genes.     

The role of introns in repeat protein gene formation

Genes composed of tandem repetitive sequence motifs are abundant in nature and are enriched in eukaryotes. To investigate repeat protein gene formation mechanisms, we have conducted a large-scale analysis of their introns and exons. We find that a wide variety of repeat motifs exhibit a striking conservation of intron position and phase, and are composed of exons that encode one or two complete repeats. These results suggest a simple model of repeat protein gene formation from local duplications. This model is corroborated by amino acid sequence similarity patterns among neighboring repeats from various repeat protein genes. The distribution of one- and two-repeat exons indicates that intron-facilitated repeat motif duplication, in which the start and end points of duplication are located in consecutive intronic regions, significantly exceeds intron-independent duplication. These results suggest that introns have contributed to the greater abundance of repeat protein genes in eukaryotic versus prokaryotic organisms, a conclusion that is supported by taxonomic analysis.     

Evolution of the immunodominant domain of the circumsporozoite protein gene from Plasmodium vivax. Implications for vaccines

Recent work directed toward the development of a malarial vaccine has focused on the identification and production of the immunodominant repeating peptide of the circumsporozoite protein of the human malaria parasites as an antigen. An important factor which relates to the usefulness of this antigen in a vaccine is the rate at which the molecule changes in sequence. We have determined the sequence and arrangement of the repeating epitope of the circumsporozoite protein gene from a Plasmodium vivax isolate from La Paz, El Salvador (Sal-I). This is compared with a portion of the previously published sequence of the circumsporozoite protein gene from a P. vivax isolate from Belém, Brazil. The genes appear to be very similar in the repeat region. There are 20 similar repeating units in the El Salvador strain and only 19 units are conserved in the Brazilian strain. Following this there are degenerate repeats in both strains. Even the pattern of silent mutations in the repeat area are similar; however, they are not necessarily in the identical location and appear to have shifted. The data suggest that the repeat region of these genes may be evolving by an accelerated mechanism(s). Such a phenomenon could severely decrease the long-term efficacy of a repeat-based anti-sporozoite vaccine.     

Evolutionary conservation and selection of human disease gene orthologs in the rat and mouse genomes

Background

Model organisms have contributed substantially to our understanding of the etiology of human disease as well as having assisted with the development of new treatment modalities. The availability of the human, mouse and, most recently, the rat genome sequences now permit the comprehensive investigation of the rodent orthologs of genes associated with human disease. Here, we investigate whether human disease genes differ significantly from their rodent orthologs with respect to their overall levels of conservation and their rates of evolutionary change.

Results

Human disease genes are unevenly distributed among human chromosomes and are highly represented (99.5%) among human-rodent ortholog sets. Differences are revealed in evolutionary conservation and selection between different categories of human disease genes. Although selection appears not to have greatly discriminated between disease and non-disease genes, synonymous substitution rates are significantly higher for disease genes. In neurological and malformation syndrome disease systems, associated genes have evolved slowly whereas genes of the immune, hematological and pulmonary disease systems have changed more rapidly. Amino-acid substitutions associated with human inherited disease occur at sites that are more highly conserved than the average; nevertheless, 15 substituting amino acids associated with human disease were identified as wild-type amino acids in the rat. Rodent orthologs of human trinucleotide repeat-expansion disease genes were found to contain substantially fewer of such repeats. Six human genes that share the same characteristics as triplet repeat-expansion disease-associated genes were identified; although four of these genes are expressed in the brain, none is currently known to be associated with disease.

Conclusions

Most human disease genes have been retained in rodent genomes. Synonymous nucleotide substitutions occur at a higher rate in disease genes, a finding that may reflect increased mutation rates in the chromosomal regions in which disease genes are found. Rodent orthologs associated with neurological function exhibit the greatest evolutionary conservation; this suggests that rodent models of human neurological disease are likely to most faithfully represent human disease processes. However, with regard to neurological triplet repeat expansion-associated human disease genes, the contraction, relative to human, of rodent trinucleotide repeats suggests that rodent loci may not achieve a 'critical repeat threshold' necessary to undergo spontaneous pathological repeat expansions. The identification of six genes in this study that have multiple characteristics associated with repeat expansion-disease genes raises the possibility that not all human loci capable of facilitating neurological disease by repeat expansion have as yet been identified.     

炭疽杆菌芽孢外壁胶原样蛋白(BclA)的多态性分析

炭疽杆菌芽孢外壁胶原样蛋白（BclA）是芽孢外壁发状菌丝的主要结构成分,也是芽孢的主要免疫原。从国内分离的3株炭疽杆菌中克隆出BclA基因并进行了序列分析,结果发现有2株（A16R和40048）的BclA与国外报道菌株长度不同,分别含有388个和322个氨基酸,72个和50个GXX三氨基酸重复序列,5个和3个含21个氨基酸的（GPT）5 GDTGTT重复序列（BclA重复）。另一株40022的BclA与国外报道的53169株完全一敛,含有370个氨基酸,66个GXX重复,5个BclA重复。对我国炭疽杆菌BclA蛋白多态性的分析为进行炭疽杆菌的基因分型以及研究炭疽芽孢的免疫原性和致病机理打下基础。     

Structure of the sea urchin U1 RNA repeat.

The genes coding for U1 RNA in the sea urchin L. variegatus are present in a 1400 base pair tandem repeat. One member of the repeat has been cloned and its sequence determined. The repeat unit contains a single copy of the gene for L. variegatus U1 RNA. This gene encodes an RNA which is 75% homologous to mammalian U1 RNA. The L. variegatus U1 RNA could assume a secondary structure similar to that proposed for other U1 RNAs. In addition the L. variegatus U1 RNA is precipitated by anti-SM and anti-RNP antisera. Analysis of the L. variegatus genomic DNA using the cloned U1 gene as a probe reveals a major and a minor type of repeat unit. The two repeated units are the same length but differ in a number of restriction enzyme sites clustered 200-500 bases down-stream from the gene. The monomer we have cloned and sequenced is a representative of the minor repeat. A sequence (GATAA) which is -41 to -37 bases 5' to the gene has homology to the putative RNA polymerase II promoter. Fifteen bases 3' of the gene is a sequence (CAAAGAAAGAAAA) which is very similar to the sequence found 3' of the sea urchin histone genes. The two Hha I, Hpa II and Ava I sites in the repeat are all unmethylated in sperm DNA.