Genetic structure of Mexican Mestizos with type 2 diabetes mellitus based on three STR loci

Background

The aims of this population genetics study were: 1) to ascertain whether Mexicans with type 2 diabetes mellitus (DM) were genetically homogeneous and 2) to compare the genetic structure of this selected population with the previously reported data of four random populations (Nuevo León, Hispanics, Chihuahua, and Central Region of Mexico).

Methods

A sample of 103 unrelated individuals with DM and whose 4 grandparents were born in five zones of Mexico was interviewed in 32 Medical Units in the Mexican Institute of Social Security (IMSS). The non-coding STRs D16S539, D7S820, and D13S317 were analyzed.

Results

Genotype distribution was in agreement with Hardy–Weinberg expectations for all three markers. Allele frequencies were found to be similar between the selected population and the four random populations. Gene diversity analysis suggested that more than 99.57% of the total gene diversity could be attributed to variation between individuals within the population and 0.43% between the populations.

Conclusions

According to the present and previous studies using molecular and non-molecular nuclear DNA markers not associated with any disease, the Mexican Mestizo population is found to be genetically homogeneous and therefore the genetic causes of DM are less heterogeneous, thereby simplifying genetic epidemiological studies as has been found in a previous study with the same design in Mexican women with breast cancer.     

3′ creatine kinase (M-type) polymorphisms linked to myotonic dystrophy in Italian and Spanish populations

Summary Linkage analysis and haplotype characterization for the allelic system detected at the 3 creatine kinase muscle type (CKMM) locus were carried out in 59 myotonic dystrophy (DM) families from Italy and Spain. A maximum lod score (z _max) of 21.26 at a recombination frequency () of 0.00 was found. No statistically significant linkage disequilibrium was observed between DM and the RFLPs examined. However, a substantial linkage disequilibrium was found between CKMM-TaqI and CKMM-NcoI sites in these two populations.     

Hemoglobin Constant Spring among Southeast Asian Populations: Haplotypic Heterogeneities and Phylogenetic Analysis

Background

Hemoglobin Constant Spring (Hb CS) is an abnormal Hb caused by a mutation at the termination codon of α2-globin gene found commonly among Southeast Asian and Chinese people. Association of Hb CS with α°-thalassemia leads to a thalassemia intermedia syndrome commonly encountered in the region. We report chromosome background and addressed genetic origins of Hb CS observed in a large cohort of Hb CS among Southeast Asian populations.

Materials and Methods

A study was done on 102 Vietnamese (aged 15–49 year-old) and 40 Laotian (aged 18–39 year-old) subjects with Hb CS and results compared with 120 Hb CS genes in Thailand. Hematological parameters were recorded and Hb analysis was performed using capillary electrophoresis. Hb CS mutation and thalassemia genotypes were defined by DNA analysis. Six DNA polymorphisms within α-globin gene cluster including 5’Xba I, Bgl I, Inter-zeta HVR, AccI, RsaI and αPstI 3’, were determined using PCR-RFLP assay.

Results

Nine different genotypes of Hb CS were observed. In contrast to the Thai Hb CS alleles which are mostly linked to haplotype (+—S + + -), most of the Vietnamese and the Laotian Hb CS genes were associated with haplotype (+—M + + -), both of which are different from that of the European Hb CS.

Conclusions

Hb CS is commonly found in combination with other thalassemias among Southeast Asian populations. Accurate genotyping of the cases requires both hematologic and DNA analyses. At least two independent origins are associated with the Hb CS gene which could indirectly explain the high prevalence of this Hb variant in the region.     

Genetic structure based on nuclear and chloroplast microsatellite loci of Solanum lycocarpum A. St. Hil. (Solanaceae) in Central Brazil

Solanum lycocarpum (Solanaceae) is a woody species found in the Brazilian Cerrado. The flowers are pollinated by Xylocopa spp bees, and seeds are dispersed by mammals with distinct home range sizes. As a consequence, relative contributions of pollen and seeds to overall gene flow can vary according to different spatial scales. We studied the genetic structure of four natural populations of S. lycocarpum separated by 19 to 128 km, including individuals located along dirt roads that interlink three of the populations. A total of 294 individuals were genotyped with five nuclear and six chloroplast microsatellite markers. Significant spatial genetic structure was found in the total set of individuals; the Sp statistic was 0.0086. Population differentiation based on the six chloroplast microsatellite markers (θ(pC) = 0.042) was small and similar to that based on the five nuclear microsatellite markers (θ(p) = 0.054). For this set of populations, pollen and seed flow did not differ significantly from one another (pollen-to-seed flow ratio = 1.22). Capability for long distance seed dispersion and colonization of anthropogenic sites contributes to the ability of S. lycocarpum to maintain genetic diversity. Seed dispersion along dirt roads may be critical in preserving S. lycocarpum genetic diversity in fragmented landscapes.     

Predicting genomic selection efficiency to optimize calibration set and to assess prediction accuracy in highly structured populations

Key message

We propose a criterion to predict genomic selection efficiency for structured populations. This criterion is useful to define optimal calibration set and to estimate prediction reliability for multiparental populations.

Abstract

Genomic selection refers to the use of genotypic information for predicting the performance of selection candidates. It has been shown that prediction accuracy depends on various parameters including the composition of the calibration set (CS). Assessing the level of accuracy of a given prediction scenario is of highest importance because it can be used to optimize CS sampling before collecting phenotypes, and once the breeding values are predicted it informs the breeders about the reliability of these predictions. Different criteria were proposed to optimize CS sampling in highly diverse panels, which can be useful to screen collections of genotypes. But plant breeders often work on structured material such as biparental or multiparental populations, for which these criteria are less adapted. We derived from the generalized coefficient of determination (CD) theory different criteria to optimize CS sampling and to assess the reliability associated to predictions in structured populations. These criteria were evaluated on two nested association mapping (NAM) populations and two highly diverse panels of maize. They were efficient to sample optimized CS in most situations. They could also estimate at least partly the reliability associated to predictions between NAM families, but they could not estimate differences in the reliability associated to the predictions of NAM families using the highly diverse panels as calibration sets. We illustrated that the CD criteria could be adapted to various prediction scenarios including inter and intra-family predictions, resulting in higher prediction accuracies.

     

Analysis of 14 cystic fibrosis mutations in five South European populations

Summary We have analysed five Southern European populations (Albanian, Greek, Italian, Spanish and Yugoslavian) for 14 cystic fibrosis (CF) mutations. The most frequent mutations, apart from F508, were G542X (6.04%), R1162X (3.61%) and N1303K (3.24%). Each of the other analysed mutations were present at a frequency of less than 1% (R347P, R334W, S549RA, S549I, G551D, R553X and W1282X), and four mutations (D110H, I507, S549RT, and S1255X) were not found in this sample. The data presented here allows the use of mutation analysis in 69.5% of Spanish, 58% of Greek, and 56.5% of Italian CF cases.     

Combined procedure of distance geometry and restrained molecular dynamics techniques for protein structure determination from nuclear magnetic resonance data: application to the DNA binding domain of lac repressor from Escherichia coli

The technique of two-dimensional nuclear magnetic resonance (2D-NMR) has recently assumed an active role in obtaining information on structures of polypeptides, small proteins, sugars, and DNA fragments in solution. In order to generate spatial structures from the atom-atom distance information obtained by the NMR method, different procedures have been developed. Here we introduce a combined procedure of distance geometry (DG) and molecular dynamics (MD) calculations for generating 3D structures that are consistent with the NMR data set and have reasonable internal energies. We report the application of the combined procedure on the lac repressor DNA binding domain (headpiece) using a set of 169 NOE and 17 "hydrogen bond" distance constraints. Eight of ten structures generated by the distance geometry algorithm were refined within 10 ps MD simulation time to structures with low internal energies that satisfied the distance constraints. Although the combination of DG and MD was designed to combine the good sampling properties of the DG algorithm with an efficient method of lowering the internal energy of the molecule, we found that the MD algorithm contributes significantly to the sampling as well.     

Computation of nitroxide-nitroxide distances in spin-labeled DNA duplexes

Nanometer distances in nucleic acids can be measured by EPR using two 1-oxyl-2,2,5,5-tetramethylpyrroline radicals, with each label attached via a methylene group to a phosphorothioate-substituted backbone position as one of two phosphorothioate diastereomers (R(P) and S(P)). Correlating the internitroxide distance to the geometry of the parent molecule requires computational analysis of the label conformers. Here, we report sixteen 4-ns MD simulations on a DNA duplex d(CTACTGCTTTAG) .d(CTAAAGCAGTAG) with label pairs at C7/C19, T5/A17, and T2/T14, respectively. For each labeled duplex, four simulations were performed with S(P)/S(P), R(P)/R(P), S(P)/R(P), and R(P)/S(P) labels, with initial all trans label conformations. Another set of four simulations was performed for the 7/19-labeled duplex using a different label starting conformation. The average internitroxide distance r(MD) was within 0.2 A for the two sets of simulations for the 7/19-labeled duplex, indicating sufficient sampling of conformational space. For all three labeled duplexes studied, r(MD) agreed with experimental values, as well as with average distances obtained from an efficient conformer search algorithm (NASNOX). The simulations also showed that the labels have conformational preferences determined by the linker chemistry and label-DNA interactions. These results establish computational algorithms that allow use of the 1-oxyl-2,2,5,5-tetramethylpyrroline label for mapping global structures of nucleic acids.     

Comparisons between Geographically Diverse Samples of Carried Staphylococcus aureus

Approximately one-third of the human population is asymptomatically colonized by Staphylococcus aureus. However, much of the global diversity within the carriage populations remains uncharacterized, and it is unclear to what degree the variation is geographically partitioned. We isolated 300 carriage isolates from 1,531 adults contemporaneously in four countries: France, Algeria, Moldova, and Cambodia. All strains were characterized by multilocus sequence typing. Six clonal complexes (CCs) were present in all four samples (CC30, -45, -121, -15, -5, and -8). Analyses based on the genotype frequencies revealed the French and Algerian samples to be most similar and the Cambodian sample to be most distinct. While this pattern is consistent with likely rates of human migration and geographic distance, stochastic clonal expansion also contributes to regional differences. Phylogenetic analysis revealed a highly divergent and uncharacterized genotype (ST1223) within Cambodia. This lineage is related to CC75, which has previously been observed only in remote aboriginal populations in northern Australia.Although better known as an important human pathogen, Staphylococcus aureus is typically a commensal species and asymptomatically colonizes approximately one-third of the human population globally (18, 20, 29). This high carriage rate potentially represents a vast reservoir of as-yet-uncharacterized S. aureus diversity, an appreciation of which should shed light on the forces underpinning the diversification and dissemination of S. aureus. There are comparatively few studies examining spatial or temporal genotype distributions within carriage populations, and the extent of biogeographical structure is currently unclear, as is the level of discrimination which might be required to detect such structure.Multilocus sequence typing (MLST) has proved to be very successful as an epidemiological tool in that it delimits S. aureus in to a small number of widespread and discrete clonal complexes (CCs) (6, 8). These can be readily identified as clusters of related genotypes which have diversified radially from “founder” genotypes (9), and because this organism is largely clonal (8), assignments of isolates to these groups is broadly robust to the many different typing methods employed (4, 10, 27). The high level of divergence between these lineages suggests that they are relatively ancient and temporally stable (7), and it is possible that isolated host populations may have been colonized by different S. aureus lineages in the past. However, any footprints of geographical partitioning are likely to have been compromised by high rates of migration in recent times, due largely to the advent of air travel.Previous studies addressing the characterization of carried populations have tended to focus on samples from Western Europe or North America, and these have generally not provided strong evidence for geographical structuring. In a recent study using amplified fragment length polymorphism to compare the carried populations in Holland and North America, the authors noted considerable overlap between the samples, suggesting that they effectively constituted a single unstructured population (17). Similarly, independent MLST studies have revealed regional consistencies in Europe, such as the predominance of CC30 in the United Kingdom (8), Ireland (3), and Switzerland (25). Given the high rates of admixture within Europe and North America, the absence of obvious geographical structuring in the carried S. aureus population in these regions is perhaps not very surprising.Although they are currently scarce, current data from carriage populations outside of Europe or North America point to greater geographical structuring. For example, a sample of carried S. aureus recovered from Bamako, Mali, has recently been characterized, constituting the first such study of an African population (23). Although many of the previously characterized CCs were also present in this sample, the authors noted a high frequency (∼25%) of a single genotype, ST152, which is phylogenetically divergent and noted very rarely in Europe. The high frequency of ST152 in this population raises the possibility that this genotype is endemic to the Malian population and possibly elsewhere in sub-Saharan Africa. This in turn hints at greater geographical partitioning on a global scale, although more representative samples are clearly required. To address this, we generated MLST data from contemporaneous carriage samples recovered from four countries representing three continents: France (Western Europe), Moldova (Eastern Europe), Algeria (North Africa), and Cambodia (Southeast Asia). To our knowledge, this is the first time such a study has been carried out on samples from Eastern Europe, North Africa, or Southeast Asia. These data were therefore generated to uncover diversity within the global carriage population but also to understand further the extent to which geographical distance and host migration can explain regional differences.     

水稻褐飞虱内生共生细菌Arsenophonus的鉴定和系统分析

利用16S rDNA通用引物扩增了水稻褐飞虱Nilaparvata lugens（Stål）体内共生细菌的序列,经克隆、测序和NCBI数据库比对,发现褐飞虱体内存在杀雄菌属Arsenophonus类共生细菌,系统发育上与粉虱科和木虱科体内的Arsenophonus属亲源关系较近。在褐飞虱体内该共生细菌具有两种长度不同的16S rDNA序列,分别为1 504 bp和547 bp,其中后者为前者中间缺失了957 bp,其余序列相同。通过重新设计两对引物进行扩增,进一步确认不同褐飞虱地理种群及寄主种群均存在两种片段。Arsenophonus特异的 23S rDNA引物的扩增结果表明,Arsenophonus存在于所有检测的褐飞虱种群中,但不存在于水稻寄主中。荧光定量PCR检测发现3个褐飞虱室内寄主种群Arsenophonus属共生细菌含量不同,其中TN1种群明显高于Mudgo种群和ASD7种群。此为水稻褐飞虱体内存在Arsenophonus属共生细菌的首次报道。     

Population structuring in the monogonont rotifer Synchaeta pectinata: high genetic divergence on a small geographical scale

相似文献   

Exchange of the Coronavirus Replicase Polyprotein Cleavage Sites Alters Protease Specificity and Processing

Coronavirus nonstructural proteins 1 to 3 are processed by one or two papain-like proteases (PLP1 and PLP2) at specific cleavage sites (CS1 to -3). Murine hepatitis virus (MHV) PLP2 and orthologs recognize and cleave at a position following a p4-Leu-X-Gly-Gly-p1 tetrapeptide, but it is unknown whether these residues are sufficient to result in processing by PLP2 at sites normally cleaved by PLP1. We demonstrate that exchange of CS1 and/or CS2 with the CS3 p4-p1 amino acids in engineered MHV mutants switches specificity from PLP1 to PLP2 at CS2, but not at CS1, and results in altered protein processing and virus replication. Thus, the p4-p1 residues are necessary for PLP2 processing but require a specific protein or cleavage site context for optimal PLP recognition and cleavage.Coronaviruses are positive-strand RNA viruses that translate their first open reading frames (ORF1a and ORF1b) into polyproteins that are processed by viral proteases into intermediate and mature nonstructural proteins (nsp1 to -16) (Fig. ​(Fig.11 A) (4, 7, 17, 20). nsp1, -2, and -3 are liberated at cleavage sites (CSs) between nsp1-2 (CS1), nsp2-3 (CS2), and nsp3-4 (CS3) by one or two papain-like protease (PLP) activities encoded within nsp3 (1, 2, 12, 13, 15) (Fig. ​(Fig.1B).1B). Murine hepatitis virus (MHV) and human coronavirus 229E (HCoV-229E) use two PLPs (PLP1 and PLP2) to process at CS1 to -3, while severe acute respiratory syndrome coronavirus (SARS-CoV) and avian infectious bronchitis virus (IBV) use a single PLP each (PLpro and PLP2, respectively) (10, 20, 25, 26). The factors determining the evolution and use of one versus two PLPs by different coronaviruses for processing of nsp1, -2, and -3 are unknown. Mutations at MHV CSs or within PLP1 alter replication and protein processing in surprising ways (8, 13). Loss of processing at MHV CS1 and CS2 by CS deletion or mutation results in changes in the timing and extent of virus replication. Inactivation of MHV PLP1 is more detrimental for virus replication than deletion of CS1 and CS2 or than inactivation of PLP1 combined with the CS deletions, even though not all of the mutant viruses process at CS1 or CS2 or display similar protein processing phenotypes. In contrast to MHV results, the HCoV-229E PLP1 and PLP2 have both been shown to process at CS1 and CS2, albeit at different efficiencies (Fig. ​(Fig.1B)1B) (24). Finally, the single SARS-CoV PLP2 homolog (PLpro) mediates efficient processing at CS1 to -3, each of which has an upstream position 4-Leu-X-Gly-Gly-position 1 (p4-LXGG-p1) amino acid motif implicated in PLpro processing (10, 16, 18). MHV possesses a p4-LXGG-p1 sequence only at CS3 and is cleaved by PLP2. These results suggest that p4-LXGG-p1 may be the critical determinant of recognition by PLP2/PLpro, but this hypothesis has not been tested in studies of replicating virus. Thus, it remains unknown whether the differences in PLP/CS recognition and processing are determined by the proximal p4-p1 residues (22).Open in a separate windowFIG. 1.MHV replicase organization, coronavirus PLP-mediated processing, and experimental design of cleavage site replacement viruses. (A) ORF1 of MHV genome RNA is shown, with overlapping ORF1a and ORF1b. The ORF1ab polyprotein is shown with nonstructural proteins (nsp1 to -16) indicated by vertical lines and numbers. Viral papain-like protease domains in nsp3 are shown as a white box containing black letters (PLP1) and a black box containing white letters (PLP2), and the nsp5 protease (3CLpro) is indicated as a gray box with a white number. Cleavage sites for PLP1 (CS1 and CS2 [shown as white arrowheads]), PLP2 (CS3 [shown as a black arrowhead]), and nsp5 (CS4 to -14 [shown as gray arrowheads]) are indicated. (B) The organization of nsp1 to nsp4 is shown for representative coronaviruses. PLPs are indicated, with the hatched box in IBV indicating a probable catalytically inactive remnant of PLP1. Processing events that were confirmed as occurring in vitro or during infection are shown by arrows with solid lines and large arrowheads, indicating single or dominant protease activity. The dashed lines and small arrowheads indicate minor or secondary cleavage activities. The CS amino acid sequences from position 4 (p4) to p1′ are shown for each CS, with a space and arrow representing the site of proteolytic processing. (C) The CS substitution viruses were engineered to replace the original CS amino acid sequences at CS1 and/or CS2 with that of the CS3 amino acid sequence p4-LKGG-p1. Both CS substitutions were also engineered into a catalytically inactive PLP1 (P1ko) background. PLPs are shown as numbers in boxes within nsp3. Engineered catalytically inactivated PLP1 is shown as a hatched box. Arrowheads indicate cleavage events of the WT virus and are linked to the enzyme predicted to mediate processing at the CS, as indicated by white boxes containing black characters (PLP1) or black boxes containing white characters (PLP2). The p4 through p1 amino acid residues for each CS are shown below each diagram. White and black vertical bars show the respective predicted PLP1 and PLP2 cleavage sites. Engineered substitutions are indicated in bold characters. Asterisks indicate engineered mutant genomes that could not be recovered as infectious virus.In this study, we used MHV as a model to test whether PLP/CS specificities could be switched by an exchange of CS amino acid sequences and to determine the impact of CS exchange on protein processing and virus replication. Replacement of the CS3 p4-LKGG-p1 at CS2, but not at CS1, was sufficient for a switch in protease specificity from PLP1 to PLP2. Some combinations of CS exchange could not be recovered with inactive PLP1, and recovered mutant viruses had altered protein processing and/or impaired growth compared to the wild type (WT). The results confirm that p4-LXGG-p1 amino acid sequences are necessary determinants of cleavage by PLP2 but also indicate that a larger cleavage site or a different protein context is required for efficient recognition and processing. Finally, the results support the conclusion that complex relationships with respect to the timing and extent of PLP/CS interactions are essential for successful replication and, likely, for virus fitness.     

Genetic diversity and population structure assessment of Chinese <Emphasis Type="Italic">Senna obtusifolia</Emphasis> L. by molecular markers and morphological traits of seed

Senna obtusifolia L. is an important medicinal plant in Asia. This study was the first report on the genetic diversity and population structure of S. obtusifolia which were collected from 47 geographic populations widespread in China. Inter-Simple Sequence Repeat (ISSR) and Start Codon Target Polymorphism (SCoT) combined with seeds morphological traits were used to investigate the relationship of 47 populations. 11 ISSR primers yielded 98 polymorphic bands with 81.67% polymorphism. 24 SCoT primers yielded 267 polymorphic bands with 89.59% polymorphism. The number of allele (Na), the number of effective allele (Ne), Nei’s diversity index (H), and Shannon’s information index (I) reflected a high level of genetic diversity of S. obtusifolia species. The greatest genetic distance (G _D) existed between Southwest and Northwest (0.4022_ISSR/0.5019_SCoT), while the Eastern and Northern showed the least genetic distance (0.1751_ISSR/0.2186_SCoT). The genetic differentiation (Gst) was 0.4875_ISSR/0.4434_SCoT, and the gene flow (Nm) was 0.5256_ISSR/0.6275_SCoT, which indicated that gene exchange among four regions was limited. 47 samples were divided into four clusters mainly according to their geographic distribution through clustering and structure analysis. The analysis on the combined data of ISSR and SCoT showed more reliable and superior results than single analysis of ISSR and SCoT. This study explored the effectiveness of ISSR and SCoT markers to evaluate the genetic diversity and population structure of S. obtusifolia and provided useful information for S. obtusifolia germplasm research and breeding program.     

Inclusion of Dried or Wet Distillers' Grains at Different Levels in Diets of Feedlot Cattle Affects Fecal Shedding of Escherichia coli O157:H7

Our objectives were to evaluate the prevalence of Escherichia coli O157:H7 in cattle fed diets supplemented with 20 or 40% dried distillers'' grains (DG) (DDG) or wet DG (WDG) and assess whether removing DG from diets before slaughter affected fecal shedding of E. coli O157:H7. Eight hundred forty steers were allocated to 70 pens (12 steers/pen). Treatments were no DG (control), 20% DDG or WDG, and 40% DDG or WDG, and each was replicated in 14 pens. In phase 1, eight floor fecal samples were collected from each pen every 2 weeks for 12 weeks for isolation of E. coli O157:H7 and detection of high shedders. In phase 2, half of the pens with DG were transitioned to the no-DG control diet, and pen floor fecal samples were collected weekly from all pens for 4 weeks. During phase 1, prevalence of E. coli O157:H7 was 20.8% and 3.2% for high shedders. The form of DG had no significant effect on fecal E. coli O157:H7 shedding. The prevalence levels of E. coli O157:H7 and the numbers of high shedders were not different between diets with 0 or 20% DG; however, cattle fed 40% DG had a higher prevalence and more high shedders than cattle fed 0 or 20% DG (P ≤ 0.05). During phase 2, overall and high-shedder prevalence estimates were 3.3% and <0.1%, respectively, and there were no differences between those for different DG forms and inclusion levels or when DG was removed from diets. The form of DG had no impact on E. coli O157:H7; however, fecal shedding was associated with the DG inclusion level.Cattle are asymptomatic reservoirs for Escherichia coli O157:H7, a food-borne pathogen associated with gastrointestinal disease in thousands of Americans each year. The organism colonizes the hindgut of cattle (18, 27) and is shed in cattle feces. Once shed, E. coli O157:H7 can contaminate food and water, creating a food safety risk (20). Contamination of beef products occurs during slaughter and is associated with the prevalence of E. coli O157:H7 in feces and on the hides of cattle at harvest (5, 8, 12).The prevalence of E. coli O157:H7 in cattle is associated with many factors, including season, geographic location, and diet. Previous work has shown that cattle fed diets containing distillers'' grains (DG), an ethanol fermentation coproduct, have a higher prevalence of E. coli O157:H7 than cattle fed diets without DG (10, 28). Distillers'' grains are a valuable feed commodity for cattle producers, and use of these coproducts has increased with the expansion of the ethanol industry (14, 17). Distillers'' grains for use in cattle diets are available in wet (WDG) or dry (DDG) form. The association between feeding DG and E. coli O157:H7 prevalence has been shown with both forms (10, 28), but no study has directly compared the two forms. The levels of DG supplementation in cattle diets generally range from 10 to 50% (dry matter basis) depending on whether the coproduct is used as a protein or energy source. As a protein supplement, DG is included at 10 to 15%; as an energy source, the DG level is generally dictated by coproduct availability and grain price (14). There is some indication that E. coli O157:H7 prevalence is different for cattle fed different levels of DG (19). However, no study has specifically evaluated the relationship between E. coli O157:H7 prevalence and DG inclusion level. Evaluation of these two factors (form and inclusion level) is important for furthering our understanding of the association between DG and E. coli O157:H7 in cattle.We also were interested in determining whether removing the DG component of the diet would lower fecal prevalence of E. coli O157:H7. Such a strategy may lead to potential mitigation options and would provide further evidence of a positive association between feeding DG and E. coli O157:H7 prevalence in cattle. In this two-phase study, our objectives were to (i) concurrently evaluate the effect of DG inclusion level and form on E. coli O157:H7 prevalence in feedlot cattle and (ii) determine if removing DG from cattle diets subsequently reduces the fecal prevalence of E. coli O157:H7.     

Diabetes mellitus and mortality after acute coronary syndrome as a first or recurrent cardiovascular event

Background

Diabetes Mellitus (DM) is associated with adverse cardiovascular prognosis. However, the risk associated with DM may vary between individuals according to their overall cardiovascular risk burden. Therefore, we aimed to determine whether DM is associated with poor outcome in patients presenting with Acute Coronary Syndrome (ACS) according to the index episode being a first or recurrent cardiovascular event.

Methods and Findings

We conducted a retrospective analysis of a prospective cohort study involving 2499 consecutively admitted patients with confirmed ACS in 11 UK hospitals during 2003. Usual care was provided for all participants. Demographic factors, co-morbidity and treatment (during admission and at discharge) factors were recorded. The primary outcome was all cause mortality (median 2 year follow up), compared for cohorts with and without DM according to their prior cardiovascular disease (CVD) disease status. Adjusted analyses were performed with Cox proportional hazards regression analysis. Within the entire cohort, DM was associated with an unadjusted 45% increase in mortality. However, in patients free of a history of CVD, mortality of those with and without DM was similar (18.8% and 19.7% respectively; p = 0.74). In the group with CVD, mortality of patients with DM was significantly higher than those without DM (46.7% and 33.2% respectively; p<0.001). The age and sex adjusted interaction between DM and CVD in predicting mortality was highly significant (p = 0.002) and persisted after accounting for comorbidities and treatment factors (p = 0.006). Of patients free of CVD, DM was associated with smaller elevation of Troponin I (p<0.001). However in patients with pre-existing CVD Troponin I was similar (p = 0.992).

Conclusions

DM is only associated with worse outcome after ACS in patients with a pre-existing history of CVD. Differences in the severity of myocyte necrosis may account for this. Further investigation is required, though our findings suggest that aggressive primary prevention of CVD in patients with DM may have beneficially modified their first presentation with (and mortality after) ACS.     

Accumulation of bacteriophage T7 head-related particles in an Escherichia coli mutant.

We have analyzed the structure of the late cytoplasmic RNAs made after infection with wild-type simian virus 40 and a set of viable mutants, four of which have deletions and one an insertion within the nucleotide sequence specifying the leader segment of the 16S and 19S mRNA's. The principal findings are: (i) simian virus 40 16S and 19S mRNA's made during infections with wild-type virnds and possibly in the nucleotide sequence comprising the "leader" segments. (II) "Spliced" 16S and 19S mRNA's are made during infections with each of the mutants although, in some cases, the ratio of 19S to 16S mRNA species is reduced. (iii) The deletion or insertion of nucleotides within the DNA segment defined by map position 0.70 to 0.75 causes striking alterations in the types of leader structures in the late mRNAs. (iv) Many of the late RNA leader segments produced after infection with the mutants appear to be multiply spliced, i.e., instead of the major 200- to 205-nucleotide-long leader segment present in wild-type 16S mRNA, the RNAs produced by several of the deletion mutants have leaders with whort discontiguous segments.     

Sequence analysis of the junctions between a large inverted repeat and single-copy regions in tobacco chloroplast DNA

Summary Tobacco chloroplast DNA contains a large inverted repeat sequence of 26 kilobase pairs (kbp). The inverted repeat is separated by 20 kbp small single-copy and 90 kbp large single-copy regions. We have cloned four DNA fragments containing each junction between the inverted repeat and the single-copy regions. The sequence analysis revealed the exact edges of the inverted repeat. A putative coding region for a ribosomal protein CS19 was found 4 base pairs (bp) away from the inverted repeat on the left margin of the large single-copy region. A sequence AGGAG, which is complementary to the 3 terminal sequence of tobacco chloroplast 16S rRNA, was found within the inverted repeat. A tRNA^His gene was found 5 bp away from the inverted repeat on the right-hand margin of the large single-copy region.     

Mapping the Structural Topology of the Yeast 19S Proteasomal Regulatory Particle Using Chemical Cross-linking and Probabilistic Modeling

Structural characterization of proteasome complexes is an essential step toward understanding the ubiquitin-proteasome system. Currently, high resolution structures are not available for the 26S proteasome holocomplex as well as its subcomplex, the 19S regulatory particle (RP). Here we have employed a novel integrated strategy combining chemical cross-linking with multistage tandem mass spectrometry to define the proximity of subunits within the yeast 19S RP to elucidate its topology. This has resulted in the identification of 174 cross-linked peptides of the yeast 19S RP, representing 43 unique lysine-lysine linkages within 24 nonredundant pair-wise subunit interactions. To map the spatial organization of the 19S RP, we have developed and utilized a rigorous probabilistic framework to derive maximum likelihood (ML) topologies based on cross-linked peptides determined from our analysis. Probabilistic modeling of the yeast 19S AAA-ATPase ring (i.e., Rpt1–6) has produced an ML topology that is in excellent agreement with known topologies of its orthologs. In addition, similar analysis was carried out on the 19S lid subcomplex, whose predicted ML topology corroborates recently reported electron microscopy studies. Together, we have demonstrated the effectiveness and potential of probabilistic modeling for unraveling topologies of protein complexes using cross-linking data. This report describes the first study of the 19S RP topology using a new integrated strategy combining chemical cross-linking, mass spectrometry, and probabilistic modeling. Our results have provided a solid foundation to advance our understanding of the 19S RP architecture at peptide level resolution. Furthermore, our methodology developed here is a valuable proteomic tool that can be generalized for elucidating the structures of protein complexes.Basic cellular homeostasis depends on the regulated protein degradation and turnover by the ubiquitin-proteasome system (1, 2). Central to this pathway is the 26S proteasome complex, which is responsible for ubiquitin/ATP-dependent protein degradation (3–5). The 26S holocomplex is a megadalton-sized protein assembly consisting of the 20S catalytic core particle (CP)¹ and the 19S regulatory particle (RP). The eukaryotic 20S CP is composed of two copies of 14 nonidentical subunits (α_1–7 and β_1–7) arranged into four stacked heptameric rings in an order of α₇β₇β₇α₇. The crystal structure and topology of the highly ordered 20S CP has been resolved and is evolutionarily conserved (6). Although α subunits of the 20S CP are essential for the assembly of the complex and its interactions with the regulatory complex, three catalytic β subunits (β1, β2, and β5) harbor various catalytic activities responsible for regulated proteasomal degradation. The 19S RP is composed of 19 subunits, which forms two subcomplexes, the base consisting of six related AAA-ATPase (Rpt1–6) and four non-ATPase (Rpn1, Rpn2, Rpn10, and Rpn13) subunits and the lid containing nine non-ATPase subunits (Rpn3, Rpn5–9, Rpn11, Rpn12, and Rpn15/Sem1) (7, 8). In comparison with the 20S core, the function and structure of the 19S RP is much less well understood. Nevertheless, it is believed that the 19S RP is involved in multiple functions including recognition of polyubiquitinated substrates (9, 10), cleavage of the polyubiquitin chains to recycle ubiquitin (11), unfolding of substrates, assisting in opening the gate of the 20S chamber, and subsequently translocating the unfolded substrates into the catalytic chamber (4, 12–14). The six AAA-ATPase subunits (Rpt1–6), which directly interact with the 20S α-ring, function as a molecular chaperone responsible for protein unfolding and are involved in substrate translocation and modulating gating of the CP (5, 15). Although detailed functions for most of the 19S non-ATPase subunits remain elusive, Rpn11 is known to carry an Mpr1p and Pad1p N-termini (MPN) domain, which harbors an essential deubiquitination activity responsible for cleaving polyubiquitin chains from proteasomal substrates (11, 16). In addition, two proteasome subunits, Rpn10 and Rpn13, have been identified as ubiquitin receptors, which are important in docking ubiquitinated substrates to the proteasome for degradation (4). Moreover, the two largest proteasome subunits, Rpn1 and Rpn2, interact with a variety of proteins including ubiquitin receptors and deubiquitinases and thus may function as scaffolding proteins to assist proteasomal degradation. Thus far, no atomic resolution structures are available for either the 19S RP or the 26S holocomplex. New insights of the overall topology of the 19S RP will illuminate protein interactions within, thus providing evidence for its otherwise unknown functions.Although many studies have been performed to characterize the 19S structure utilizing various techniques including cryo-EM (17, 18) and native mass spectrometry (19), details on spatial interfaces and subunit interconnectivity of the 19S RP remain to be unraveled. During the course of our study, the rough topology of the 19S RP was determined by cryo-EM alone (20) or coupled with other approaches (21); nevertheless more detailed information at the peptide or atomic level is still required. In addition to technological limitations in current approaches, the highly dynamic and heterogeneous nature of the 19S RP may attribute to the difficulty in obtaining its high resolution structure. In recent years, chemical cross-linking coupled with mass spectrometry (XL-MS) has become an attractive alternative for structure analysis of proteins and protein complexes (22, 23). The ability of XL-MS to identify interaction interfaces between proteins allows us to define low resolution protein topology. In addition to protein interaction networks and the site of protein interactions at binding interfaces, cross-linking analysis can reveal information about the spatial distance between cross-linked amino acids on the surface of folded proteins. Although such knowledge only reveals the maximum distance given by the length of the cross-linker and can be influenced by protein conformational flexibility, it can be used as the distance constraint for molecular modeling of protein folds and complex topologies, i.e., the arrangement of the constituents of a complex in space. A recent study by Chen et al. (24) on yeast RNA polymerase II (RNAPII) complex has exemplified the power of XL-MS in elucidating the architecture of large multisubunit complexes. Although effective, cross-linking studies have been challenging because of the low abundance of cross-linked products and the inherent complexity of sequencing interlinked peptides by MS for unambiguous identification. To facilitate MS detection and identification of cross-linked products, we have recently developed a novel homobifunctional amine reactive, low energy MS-cleavable cross-linker, disuccinimidyl sulfoxide (DSSO), and successfully applied it to cross-link the yeast 20S proteasome for rapid, accurate, and simplified determination of protein interaction interfaces within the complex (25). The unique functionality of our cross-linking reagent and specialized bioinformatics tools significantly increase our confidence and speed in the identification of cross-linked products when compared with cross-linking studies using traditional noncleavable reagents. Current cross-linking studies have been focused on protein complexes with known crystal structures, but topological structures of protein complexes based primarily on cross-linking data have not yet been reported. This is due to the lack of computational tools that use cross-linking data to deduce the spatial organization of subunits in a given complex. To define the architecture of the yeast 19S RP, we have characterized the proximity and interconnectivity of the subunits by employing our newly developed cross-linking strategy. The resulting cross-linking information serves as a basis for a rigorous probabilistic analysis to obtain the maximum likelihood (ML) topology. This strategy is developed by first analyzing our cross-linking data for the 19S six-member AAA-ATPase base ring, as the topology ordering of yeast orthologs has been recently determined (14, 26–28). The effectiveness of this new probabilistic platform is supported by the agreement between our derived ML topology of the AAA-ATPase base ring and previous reports. When the same probabilistic approach is applied to the 19S lid subcomplex, the resulting topology is also in agreement with recently proposed models (20, 21). This work represents the first application of probabilistic modeling of protein complexes based solely on cross-link data, establishing a new workflow for future structural analysis of large protein complexes using XL-MS.