Occurrence of periodontal pathogens among patients with chronic periodontitis

The aim of the present study was to evaluate the presence of the periodontal pathogens that form the red complex (Tannerella forsythia, Porphyromonas gingivalis and Treponema denticola) and Aggregatibacter actinomycetemcomitans in patients with chronic periodontitis. The sample consisted of 29 patients with a clinical and radiographic diagnosis of chronic periodontitis based on the criteria of the American Academy of Periodontology (3). Samples for microbiological analysis were collected from the four sites of greatest probing depth in each patient, totaling 116 samples. These samples were processed using conventional polymerase chain reaction, which achieved the following positive results: 46.6% for P. gingivalis, 41.4% for T. forsythia, 33.6% for T. denticola and 27.6% for A. actinomycetemcomitans. P. gingivalis and T. forsythia were more prevalent (p < 0.05) in periodontal pockets ≥ 8 mm. The combinations T. forsythia + P. gingivalis (23.2%) and T. forsythia + P. gingivalis + T. denticola (20.0%) were more frequent in sites with a probing depth ≥ 8 mm. Associations with the simultaneous presence of A. actinomycetemcomitans + P. gingivalis, A. actinomycetemcomitans + T. forsythia, P. gingivalis + T. forsythia and T. forsythia + T. denticola were statistically significant (p < 0.05). It was concluded that the red complex pathogens are related to chronic periodontitis, presenting a higher occurrence in deep periodontal pockets. Moreover, the simultaneous presence of these bacteria in deep sites suggests a symbiotic relationship between these virulent species, favoring, in this way, a further progression of periodontal disease.

Occurrence of periodontal pathogens among patients with chronic periodontitis.

The aim of the present study was to evaluate the presence of the periodontal pathogens that form the red complex (Tannerella forsythia, Porphyromonas gingivalis and Treponema denticola) and Aggregatibacter actinomycetemcomitans in patients with chronic periodontitis. The sample consisted of 29 patients with a clinical and radiographic diagnosis of chronic periodontitis based on the criteria of the American Academy of Periodontology (3). Samples for microbiological analysis were collected from the four sites of greatest probing depth in each patient, totaling 116 samples. These samples were processed using conventional polymerase chain reaction, which achieved the following positive results: 46.6% for P. gingivalis, 41.4% for T. forsythia, 33.6% for T. denticola and 27.6% for A. actinomycetemcomitans. P. gingivalis and T. forsythia were more prevalent (p < 0.05) in periodontal pockets ≥ 8 mm. The combinations T. forsythia + P. gingivalis (23.2%) and T. forsythia + P. gingivalis + T. denticola (20.0%) were more frequent in sites with a probing depth ≥ 8 mm. Associations with the simultaneous presence of A. actinomycetemcomitans + P. gingivalis, A. actinomycetemcomitans + T. forsythia, P. gingivalis + T. forsythia and T. forsythia + T. denticola were statistically significant (p < 0.05). It was concluded that the red complex pathogens are related to chronic periodontitis, presenting a higher occurrence in deep periodontal pockets. Moreover, the simultaneous presence of these bacteria in deep sites suggests a symbiotic relationship between these virulent species, favoring, in this way, a further progression of periodontal disease.

Informativeness of a novel multiallelic marker-set comprising an F8 intron 21 and three tightly linked loci for haemophilia A carriership analysis.

The extraordinary heterogeneous nature of the deleterious mutations in the F8 gene that lead to functional deficiency of clotting factor VIII in haemophilia A makes routine direct mutation profiling difficult. When direct mutation analysis cannot be performed or a causative/candidate mutation is not found, a second-line approach to track the defective F8 gene within at-risk families is linkage genetic analysis with, tried-and-tested, F8-intragenic and/or extragenic non-recombining multiallelic short tandem repeats (STR). Although several typing STR loci within and around F8 have been described, there is need for improving assessment, because the combined informativeness of available assays rarely reaches 100%. Here, we characterized a newly identified 0.28 cM-resolution marker-set, consisting of a dinucleotide STR located on F8 intron 21 (F8Int21; [AC](n)) and three extragenic tetranucleotide STR located on GAB3 intron 1 (GAB3Int1; [TAAA](n)) and TMLHE intron 1 (TMLHEInt1.1; [GAAA](n) and TMLHEInt1.3; [ATTC](n)). Heterozygosity rates determined in 100 unrelated females ranged from 0.25 (GAB3Int1) to 0.63 (F8Int21). The set rendered a combined informativeness of 0.91 for at least one marker and 0.60 for a minimum of two loci, with at least one F8-intragenic. Multiallelic interlocus non-random association analysis revealed that GAB3Int1 is not in significant gametic disequilibrium (GD) with F8Int21, F8Int9.2, TMLHEInt1.3 or TMLHEInt1.1. Gametic disequilibrium breakdown attests historical recombination between GAB3Int1 and the F8 gene. Through computational analysis of reference assembly sequence data, we note in the GD breakdown region and in the F8 gene a higher than average density of the 13-mer CCNCCNTNNCCNC consensus motif, commonly associated with recombination hotspots.

Double aneuploidy (48,XXY,+21) of maternal origin in a child born to a 13-year-old mother: evaluation of the maternal folate metabolism.

The occurrence of non-mosaic double trisomy is exceptional in newborns. In this paper, a 48,XXY,+21 child, the parental origin of the extra chromosomes and the evaluation of the maternal folate metabolism are presented. The infant was born to a 13-year-old mother and presented with the typical clinical features of Down syndrome (DS). The origin of the additional chromosomes was maternal and most likely resulted from errors during the first meiotic division. Molecular analysis of 12 genetic polymorphisms involved in the folate metabolism revealed that the mother is heterozygous for the MTHFR C677T and TC2 A67G polymorphisms, and homozygous for the mutant MTRR A66G polymorphism. The maternal homocysteine concentration was 4.7 miromol/L, a value close to the one considered as a risk factor for DS in our previous study. Plasma methylmalonic acid and serum folate concentrations were 0.17 micromol/L and 18.4 ng/mL, respectively. It is possible that the presence of allelic variants for the folate metabolism and Hey concentration might have favored errors in chromosomal disjunction during gametogenesis in this young mother. To our knowledge, this is the first patient with non-mosaic Down-Klinefelter born to a teenage mother, resulting from a rare fertilization event combining an abnormal 25,XX,+21 oocyte and a 23,Y spermatozoon.

Improved criterion-referenced assessment in indirect tracking of haemophilia A using a 0.23 cM-resolution dense polymorphic marker set.

In haemophilia A, linkage analysis with coagulation factor VIII (F8) intragenic and/or neighbouring extragenic short tandem repeats (STRs) enables indirect tracking F8 pathogenic allelic variant-carriers. Even where DNA sequencing is available, linkage analysis still has a role if no causative or candidate mutation is unveiled. The cumulative heterozygosity rate of the available multiplexed STRs haplotyping assays rarely reaches 100%. This means that in a proportion of women these loci are uninformative. The norm-referenced assessment is based on at least one informative marker criterion. We reasoned that by typing a dense market set, spanning a small fraction of recombination, we should be able to improve assessment. The aim of this study was to improve criterion-referenced assessment in polymorphism segregation analyses using a low-recombination fraction and dense informative STRs set. The multiplex quantitative fluorescence PCR assay comprises four novel tetranucleotide and pentanucleotide STRs distant < or = 0.15 cM from the F8 gene, and three F8 intragenic dinucleotide STRs, mapped to a 0.23 cM interval spanning the F8 on human chromosome band Xq28. We determined heterozygosity rates and allele frequencies from 100 unrelated healthy females. To investigate about segregation stability, we typed 50 true trios (mother, daughter and father) and 50 true mother-and-son duos from the general population. The heterozygosity rates for the extragenic markers ranged 0.49-0.76. The 0.23 cM-resolution heptaplex rendered a cumulative heterozygosity of 0.89 for a minimum of two informative markers, with at least one F8 intragenic. The heptaplex assay enabled improving the criterion-referenced assessment in indirect carrier-detection.

High-resolution combined linkage physical map of short tandem repeat loci on human chromosome band Xq28 for indirect haemophilia A carrier detection.

Haemophilia A, the most common severe hereditary bleeding disorder in humans, is chiefly caused by mutations in the coagulation factor VIII F8 gene, which maps on chromosome band Xq28. Linkage analysis with F8 intragenic and/or closely located extragenic short tandem repeat (STR) elements is an effective method for indirect tracing of F8 pathogenic allelic variants in at-risk families. STR profiling is currently limited to 14 markers, 11 of which are dinucleotide elements. The aim of this study was to define novel polymorphic STR loci for haemophilia A carrier screening. The combined linkage physical map was restricted to a 2.4-Mb region on Xq28 that hosts 81 annotated genes, F8 inclusive. The inventory was in silico through comparative analyses with three X chromosome reference sequences, using microsatellite mining and validation computer software. Genetic distances for unmapped markers were interpolated on the Rutgers map of the human genome. The effort yielded 94 STR loci: 53 extragenic and 41 intragenic (14 STR elements map on the F8 gene; the other 27 on 19 further genes). The distribution per repeat period size was 61.7% di-, 5.3% tri-, 26.6% tetra- and 6.4% pentanucleotide loci. The success rate of validation of polymorphism for the new STR loci was 56.3%. For STR elements 0.78 Mb equidistant of the F8 gene, the interpolated downstream genetic length is 3.27 times the upstream genetic length. The inventory represents a 5.7-fold increase in polymorphic STR loci useful in carrier detection. Genotyping with the upstream extragenic tetra- and pentanucleotide markers is thus apprized.

Neonatal hyperleptinaemia programmes adrenal medullary function in adult rats: effects on cardiovascular parameters.

Epidemiological studies have shown a strong correlation between stressful events (nutritional, hormonal or environmental) in early life and development of adult diseases such as obesity, diabetes and cardiovascular failure. It is known that gestation and lactation are crucial periods for healthy growth in mammals and that the sympathoadrenal system is markedly influenced by environmental conditions during these periods. We previously demonstrated that neonatal hyperleptinaemia in rats programmes higher body weight, higher food intake and hypothalamic leptin resistance in adulthood. Using this model of programming, we investigated adrenal medullary function and effects on cardiovascular parameters in male rats in adulthood. Leptin treatment during the first 10 days of lactation (8 microg 100 g(-1) day(-1), s.c.) resulted in lower body weight (6.5%, P < 0.05), hyperleptinaemia (10-fold, P < 0.05) and higher catecholamine content in adrenal glands (18.5%, P < 0.05) on the last day of treatment. In adulthood (150 days), the rats presented higher body weight (5%, P < 0.05), adrenal catecholamine content (3-fold, P < 0.05), tyrosine hydroxylase expression (35%, P < 0.05) and basal and caffeine-stimulated catecholamine release (53% and 100%, respectively, P < 0.05). Systolic blood pressure and heart rate were also higher in adult rats (7% and 6%, respectively, P < 0.05). Our results show that hyperleptinaemia in early life increases adrenal medullary function in adulthood and that this may alter cardiovascular parameters. Thus, we suggest that imprinting factors which increase leptin and catecholamine levels during the neonatal period could be involved in development of adult chronic diseases.