Altered CD161bright CD8+ Mucosal Associated Invariant T (MAIT)-Like Cell Dynamics and Increased Differentiation States among Juvenile Type 1 Diabetics

Type 1A diabetes (T1D) is believed to be caused by immune-mediated destruction of β-cells, but the immunological basis for T1D remains controversial. Microbial diversity promotes the maturation and activation of certain immune subsets, including CD161^bright CD8⁺ mucosal associated invariant T (MAIT) cells, and alterations in gut mucosal responses have been reported in type 1 diabetics (T1Ds). We analyzed T cell populations in peripheral blood leukocytes from juvenile T1Ds and healthy controls. We found that proportion and absolute number of MAIT cells were similar between T1Ds and controls. Furthermore, while MAIT cell proportions increased with age among healthy controls, this trend was not observed among long-standing T1Ds. Additionally, the CD27- MAIT cell subset is significantly increased in T1Ds and positively correlated with HbA1c levels. However, after T1Ds are stratified by age, the younger group has significantly increased proportions of CD27- MAIT cells compared to age-matched controls, and this proportional increase appears to be independent of HbA1c levels. Finally, we analyzed function of the CD27- MAIT cells and observed that IL-17A production is increased in CD27- compared to CD27⁺ MAIT cells. Overall, our data reveal disparate MAIT cell dynamics between T1Ds and controls, as well as signs of increased MAIT cell activation in T1Ds. These changes may be linked to hyperglycemia and increased mucosal challenge among T1Ds.     

Mechanism of replication of human mitochondrial DNA. Localization of the 5' ends of nascent daughter strands

Human mitochondrial DNA contains two physically separate and distinct origins of DNA replication. The initiation of each strand (heavy and light) occurs at a unique site and elongation proceeds unidirectionally. Animal mitochondrial DNA is novel in that short nascent strands are maintained at one origin (D-loop) in a significant percentage of the molecules. In the case of human mitochondrial DNA, there are three distinct D-loop heavy strands differing in length at the 5' end. We report here the localization of the 5' ends of nascent daughter heavy strands originating from the D-loop region. Analyses of the map positions of 5' ends relative to known restriction endonuclease cleavage sites and 5' end nucleotides indicate that the points of initiation of D-loop synthesis and actual daughter strands are the same. In contrast, the second origin is located two-thirds of the way around the genome where light strand synthesis is presumably initiated on a single-stranded template. Mapping of 5' ends of daughter light strands at this origin relative to known restriction endonuclease cleavage sites reveals two distinct points of initiation separated by 37 nucleotides. This origin is in the same relative genomic position and shows a high degree of DNA sequence homology to that of mouse mitochondrial DNA. In both cases, the DNA region within and immediately flanking the origin of DNA replication contains five tightly clustered tRNA genes. A major portion of the pronounced DNA template secondary structure at this origin includes the known tDNA sequences.     

Nucleotide Sequence Analysis of DNA

There are three major obstacles to the analysis of the nucleotide sequence in a DNA molecule starting from a known location in the DNA molecule. First, it is difficult to obtain large quantities of homogeneous DNA. Second, even the smallest DNA molecules contain several thousand nucleotides which make sequence analysis prohibitive. Third, there are no highly base-specific DNAases available for degrading DNA for sequence analysis. We have overcome some of these obstacles; first, by incorporating highly labelled deoxynucleotides into DNA in vitro, small amounts of material can be used for sequence analysis. Second, the nucleotide sequence of DNA molecules can now be determined from the 5′-terminal. Thus, two dodecanucleotide sequences corresponding to the two cohesive ends of λ DNA have been determined¹ and a nona-decanucleotide sequence corresponding to one cohesive end of phage 186 DNA has been completed². So far, our approach is limited to starting the analysis from the 5′-ends of a DNA molecule. A more general approach is being developed for starting the analysis from other selected parts of a DNA molecule with the use of specifically designed primers.     

Crassostrea angulata Bindin Gene and the Divergence of Fucose-Binding Lectin Repeats Among Three Species of Crassostrea

Bindin is a major protein for species-specific recognition between sperm and congenetic egg in many free-spawning marine invertebrates. We cloned a novel bindin gene from the oyster Crassostrea angulata by 3′ and 5′ rapid amplification of cDNA ends. The full-length bindin cDNA was 1,049 bp with a 771-bp open reading frame encoding 257 amino acids. The deduced amino acid sequence contained a putative signal peptide of 24 amino acids. The length of the bindin genomic DNA was 8,508 bp containing four exons and three introns. Three haplotypes of F-lectin repeat were detected from seven sequences of F-lectin repeat of six male oysters. Both neighbor-joining and minimum-evolution phylogenetic trees show that haplotype an1 was close to Crassostrea gigas while an2 and an3 were close to Crassostrea sikamea. Intron-4 in the middle of F-lectin repeat is highly variable in both size and sequence. We classified intron-4 into three types according to their size and the F-lectin repeat they were located in. Intron-4 may play an important role in recombination. We compared the number of nonsynonymous substitutions (Dn) and synonymous substitutions (Ds) per nucleotide site among 19 F-lectin haplotypes of the three species. Dn/Ds ratios suggested that positive selection occurred between C. gigas and C. sikamea and between C. gigas and C. angulata. Nine positive selected positions (p > 90%) are identified among 19 haplotypes of three species. They are located on the F-lectin binding face around the three recognition motif residues. We assume that these nine clustered amino acids are related with species-specific recognition.     

Genome of Bacillus subtilis Bacteriophage SPP1: Structure and Nucleotide Sequence of pac, the Origin of DNA Packaging

The DNA of Bacillus subtilis bacteriophage SPP1 is terminally redundant and partially circularly permuted. To explain these parameters, we followed the Streisinger-Botstein models of phage maturation and assumed that packaging of SPP1 DNA begins at a unique genomic site (“pac”) and proceeds sequentially from there. We describe the sequence of about 1,000 nucleotides surrounding pac. This together with size determinations of small, pac-terminated restriction fragments has revealed heterogeneity of the natural pac ends of SPP1 DNA. Such ends fell in each DNA strand into a region of five to seven nucleotides. However, within this range more than 50% of all molecules terminated with defined cytosines on both strands, generating a 3′ protruding terminus. The nucleotide sequence of the DNA segment surrounding pac did not reveal any features which would distinguish this region.     

A Fourier characteristic of coding sequences: origins and a non-Fourier approximation.

The 3-base periodicity, identified as a pronounced peak at the frequency N/3 (N is the length of the DNA sequence) of the Fourier power spectrum of protein coding regions, is used as a marker in gene-finding algorithms to distinguish protein coding regions (exons) and noncoding regions (introns) of genomes. In this paper, we reveal the explanation of this phenomenon which results from a nonuniform distribution of nucleotides in the three coding positions. There is a linear correlation between the nucleotide distributions in the three codon positions and the power spectrum at the frequency N/3. Furthermore, this study indicates the relationship between the length of a DNA sequence and the variance of nucleotide distributions and the average Fourier power spectrum, which is the noise signal in gene-finding methods. The results presented in this paper provide an efficient way to compute the Fourier power spectrum at N/3 and the noise signal in gene-finding methods by calculating the nucleotide distributions in the three codon positions.     

The terminal redundant regions of bacteriophage T7 DNA

Summary Some aspects of the involvment of the terminal reduntant regions of T7 DNA on phage production have been studied by transfection experiments with T7 DNA after treatment of the molecules with exonuclease or exonuclease plus exonuclease I. It was found that terminal 5 gaps between 0.08 and 6.4% of the total length did not decrease the infectivity of the molecules although such gaps cannot be filled directly by DNA polymerases. Rather, compared to fully native DNA the infectivity of gapped DNA increased up to 20 fold in rec ⁺ spheroplasts and up to 4 fold in recB spheroplasts. This indicates a protective function of the single-stranded termini against the recBC enzyme in rec ⁺ and possibly another unidentified exonuclease present also in recB. The possibility that spontaneous circularization of the gapped molecules in vivo provides protection against exonucleolytic degradation was tested by transfection with T7 DNA circularization in vitro by thermal annealing. Such molecules were separated from linear molecules by neutral sucrose gradient centrifugation. They displayed a 3 to 6 fold higher infectivity in rec ⁺ and recB compared to linear gapped molecules, which shows that T7 phage production may effectively start from circular DNA.When the 3 single-stranded ends from gapped molecules were degraded by treatment with exonuclease I the infectivity of the molecules was largely abolished in rec ⁺ and recB as soon as 40 to 80 base pairs had been removed per end. It is concluded that the terminal regions of T7 DNA molecules are essential for phage production and that the redundancy comprises probably considerably less than 260 base pairs. The results are discussed with respect to the mode of T7 DNA replication.     

Palindromic Nucleotide Analysis in Human T Cell Receptor Rearrangements

Diversity of T cell receptor (TCR) genes is primarily generated by nucleotide insertions upon rearrangement from their germ line-encoded V, D and J segments. Nucleotide insertions at V-D and D-J junctions are random, but some small subsets of these insertions are exceptional, in that one to three base pairs inversely repeat the sequence of the germline DNA. These short complementary palindromic sequences are called P nucleotides. We apply the ImmunoSeq deep-sequencing assay to the third complementarity determining region (CDR3) of the β chain of T cell receptors, and use the resulting data to study P nucleotides in the repertoire of naïve and memory CD8⁺ and CD4⁺ T cells. We estimate P nucleotide distributions in a cross section of healthy adults and different T cell subtypes. We show that P nucleotide frequency in all T cell subtypes ranges from 1% to 2%, and that the distribution is highly biased with respect to the coding end of the gene segment. Classification of observed palindromic sequences into P nucleotides using a maximum conditional probability model shows that single base P nucleotides are very rare in VDJ recombination; P nucleotides are primarily two bases long. To explore the role of P nucleotides in thymic selection, we compare P nucleotides in productive and non-productive sequences of CD8⁺ naïve T cells. The naïve CD8⁺ T cell clones with P nucleotides are more highly expanded.     

Processing of bacteriophage T4 tRNAs. The role of RNAase III

In order to assess the contribution of the processing enzyme RNAase III to the maturation of bacteriophage T4 transfer RNA, RNAase III⁺ and RNAase III^? strains were infected with T4 and the tRNAs produced were analyzed. Infection of the RNAase III⁺ strains of Escherichia coli with T4Δ27, a deletion strain missing seven of the ten genes in the T4 tRNA cluster, results in the appearance of a transient 10.1 S RNA molecule as well as the three stable RNAs encoded by T4Δ27, species 1, rRNA^Leu and tRNA^Gln. Infection of an RNAase III^? strain results in the appearance of a larger, transient RNA molecule, 10.5 S, and a severe reduction in the accumulation of tRNA^Gln. The 10.5 S RNA is similar to 10.1 S RNA but contains extra nucleotides (about 50) at the 5′ end. (10.1 S contains all the three final molecules plus about 70 extra nucleotides at the 3′ end.) Both 10.5 S and 10.1 S RNAs can be processed in vitro into the three final molecules. When 10.1 S is the substrate, the three final molecules are obtained whether extracts of RNAase III⁺ or RNAase III^? cells are used. However, when 10.5 S is the substrate RNAase III⁺ extracts bring out normal maturation, while using RNAase III^? extracts the level of tRNA^Gln is severely reduced. When 10.5 S is used with RNAase III⁺ extracts maturation proceeds via 10.1 S RNA, while when RNAase III^? extracts were used 10.1 S is not detected. The 10.5 S RNA can be converted to 10.1 S RNA by RNAase III in a reaction which produces only two fragments. The sequence at the 5′ end of the 10.5 S suggests a secondary structure in which the RNAase III cleavage site is in a stem. These experiments show that the endonucleolytic RNA processing enzyme RNAase III is required for processing at the 5′ end of the T4 tRNA cluster where it introduces a cleavage six nucleotides proximal to the first tRNA, tRNA^Gln, in the cluster.     

Genetic characteristics and genome structure of Streptomyces coelicolor actinophages]

Actinophage phi C31 of Streptomyces coelicolor A3 (2) and two novel temperate actinophages phi C43 and phi C62 isolated from strains of blue actinomycetes group are homoimmune, serologically and functionally related. DNA molecules of phages phi C31, phi C43 and phi C62 have cohesive ends; sizes of DNAs of these phages and some mutants have been determined. The extent of homology between the DNAs of three phages is 93-96% as shown by heteroduplex analysis. The regions of non-homology are of a deletion-insertion type and of approximately 1500 base pairs in the length. Location of deletions in DNAs of mutant phages phi C31 vd and phi C31 c5 has been shown. Structural modifications in phage dnas have been found only to occur in the right part of molecules. Heteroduplex maps have been constructed for all phages studied.     

EcoRI analysis of bacteriophage P22 DNA packaging.

Bacteriophage P22 linear DNA molecules are a set of circularly permuted sequences with ends located in a limited region of the physical map. This mature form of the viral chromosome is cut in headful lengths from a concatemeric precursor during DNA encapsulation. Packaging of P22 DNA begins at a specific site, which we have termed pac, and then proceeds sequentially to cut lengths of DNA slightly longer than one complete set of P22 genes (Tye et al., 1974b). The sites of DNA maturation events have been located on the physical map of EcoRI cleavage sites in P22 DNA. EcoRI digestion products of mature P22 wild-type DNA were compared with EcoRI fragments of two deletion and two insertion mutant DNAs. These mutations decrease or increase the length of the genome, but do not alter the DNA encapsulation mechanism. Thus the position of mature molecular ends relative to EcoRI restriction sites is different in each mutant, and comparison of the digests shows which fragments come from the ends of linear molecules. From the positions of the ends of molecules processed in sequential headfuls, the location of pac and the direction of encapsulation relative to the P22 map were deduced. The pac site lies in EcoRI fragment A, 4.1 × 10³ base-pairs from EcoRI cleavage site 1. Sequential packaging of the concatemer is initiated at pac and proceeds in the counterclockwise direction relative to the circular map of P22. One-third of the linears in a population are cut from the concatemer at pac, and most packaging sequences do not extend beyond four headfuls.Fragment D is produced by EcoRI cleavage at a site near the end of a linear chromosome which has been encapsulated starting at pac. The position of the pac site is therefore defined by one end of fragment D. The pac site is not located near genes 12 and 18, the only known site for initiation of P22 DNA replication, but lies among late genes at a position on the physical gene map approximately analogous to the cohesive end site (cos) of bacteriophage λ at which λ DNA is cleaved during encapsulation. Our results suggest that P22 and λ DNA maturation mechanisms have many common properties.     

Effects of DNA sequence non-homology on formation of bacteriophage lambda recombinants.

The presence of DNA sequence non-homologies limits the parental material contribution to the genomes of unduplicated bacteriophage λ recombinants. Crosses involving closely linked markers within the lacZ region of λ plac5 have been carried out under conditions severely limiting DNA synthesis. The presence of density labels distinguishing the parental phage permits an assessment of their material contribution to the lacZ recombinant phage that emerge.When both parents harbor point mutations, the recombinants exhibit a broad range of relative parental DNA contributions, providing support for the proposal that the lacZ⁺ recombinants that are detected under these conditions result from mismatch repair processes acting on heterozygous sites within the long regions of heteroduplex structure present in the products of recombination. The presence of a region of non-homology, either a deletion or an insertion sequence, in one of the parents results in a limitation in the material contribution of that parent to the recombinant products. When both parents carry regions of non-homology, the relative parental contributions to recombinant products are further limited and are confined to the density range expected of the products of double-stranded breakage and joining events within the region separating the two mutational sites. These observations suggest that regions of non-homology are excluded from heteroduplex structures and provide support for a role of branch migration of a Holliday (1964) structure in the formation of the heteroduplex regions that are present in the products of recombination.     

Complete sequence of bovine mitochondrial DNA conserved features of the mammalian mitochondrial genome

We present here the complete 16,338 nucleotide DNA sequence of the bovine mitochondrial genome. This sequence is homologous to that of the human mitochondrial genome (Anderson et al., 1981) and the genes are organized in virtually identical fashion. The bovine mitochondrial protein genes are 63 to 79% homologous to their human counterparts, and most of the nucleotide differences occur in the third positions of codons. The minimum rate of base substitution that accounts for the nucleotide differences in the codon third positions is very high: at least 6 × 10^?9 changes per position per year. The bovine and human mitochondrial transfer RNA genes exhibit more interspecies variation than do their cytoplasmic counterparts, with the “TΨC” loop being the most variable part of the molecule. The bovine 12 S and 16 S ribosomal RNA genes, when compared with those from human mitochondrial DNA, show conserved features that are consistent with proposed secondary structure models for the ribosomal RNAs. Unlike the pattern of moderate-to-high homology between the bovine and human mitochondrial DNAs found over most of the genome, the DNA sequence in the bovine D-loop region is only slightly homologous to the corresponding region in the human mitochondrial genome. This region is also quite variable in length, and accounts for the bulk of the size difference between the human and bovine mitochondrial DNAs.     

不同启动子控制下Ac转座酶基因的表达对玉米Ds因子在水稻中切离频率的影响

用水稻愈伤组织比较了Ac启动子、35S启动子与Ubi启动子控制下Ac转座酶基因（Ts）的表达对Ds因子切离频率的影响。结果表明Ubi启动子与Ac转座酶编码区嵌合基因（Ubipro-Ts）反式激活Ds因子的切离频率最高,达到了72.9%。通过杂交将Ubipro-Ts基因导入Ds因子转化植株,得到9株Ubipro-Ts基因与Ds因子共存的F1代杂交水稻植株,其中有8株Ds因子发生了切离。用Inverse-PCR的方法从其中一株杂交植株中克隆到Ds因子的旁邻序列,其DNA顺序与亲本中Ds因子原插入位点的序列不同,表明Ds因子转座到了新的基因组位点。     

Initiation site of deoxyribonucleotide polymerization at the replication origin of the Escherichia coli chromosome

A new round of chromosomal replication of a temperature-sensitive initiation mutant (dnaC) of Escherichia coli was initiated synchronously by a temperature shift from a nonpermissive to a permissive condition in the presence of arabinosyl cytosine. Increased amounts of nascent DNA fragments with homology for the chromosomal segment containing the replication origin (oriC) were found. The nascent DNA fragments were purified and treated with alkali to hydrolyze putative primer RNA and to expose 5'-hydroxyl DNA ends at the RNA-DNA junctions. The ends were then labeled selectively with T4 polynucleotide kinase and [gamma-32P]ATP at 0 degrees C and the terminally-labeled initiation fragments were purified by hybridization with origin probe DNAs containing one each of the constituent strands of oriC-DNA segment. The 32P-labeled initiation sites were then located at the resolution of single nucleotides in the nucleotide sequence of the oriC segment after cleavage with restriction enzymes. Two initiation sites of DNA synthesis, 37 nucleotides apart, were detected in one of the component strands of the oriC; in other words, in the strand whose 5' to 3' polynucleotide polarity lies counterclockwise on the E. coli genetic map. The results support the involvement of the primer RNA in the initiation of DNA synthesis at the origin of the E. coli genome and suggest that the first initiation event is asymmetric.     

Sequence and sequence variation within the 1.688 g/cm3 satellite DNA of Drosophila melanogaster.

We have determined the complete nucleotide sequence of the monomer repeating unit of the 1.688 g/cm³ satellite DNA from Drosophila melanogaster. This satellite DNA, which makes up 4% of the Drosophila genome and is located primarily on the sex chromosomes, has a repeat unit 359 base-pairs in length. This complex sequence is unrelated to the other three major satellite DNAs present in this species, each of which contains a very short repeated sequence only 5 to 10 base-pairs long. The repeated sequence is more similar to the complex repeating units found in satellites of mammalian origin in that it contains runs of adenylate and thymidylate residues. We have determined the nature of the sequence variations in this DNA by restriction nuclease cleavage and by direct sequence determination of (1) individual monomer units cloned in hybrid plasmids, (2) mixtures of adjacent monomers from a cloned segment of this satellite DNA, (3) mixtures of monomer units isolated by restriction nuclease cleavage of total 1.688 g/cm³ satellite DNA. Both direct sequence determination and restriction nuclease cleavage indicate that certain positions in the repeat can be highly variable with up to 50% of certain restriction sites having altered recognition sequences. Despite the high degree of variation at certain sites, most positions in the sequence are highly conserved. Sequence analysis of a mixture of 15 adjacent monomer units detected only nine variable positions out of 359 base-pairs. Total satellite DNA showed only four additional positions. While some variability would have been missed due to the sequencing methods used, we conclude that the variation from one repeat to the next is not random and that most of the satellite repeat is conserved. This conservation may reflect functional aspects of the repeated DNA, since we have shown earlier that part of this sequence serves as a binding site for a sequence-specific DNA binding protein isolated from Drosophila embryos (Hsieh &; Brutlag, 1979).