Mitochondrial Oxidative Stress-A Causative Factor and Therapeutic Target in Many Diseases.

The excessive formation of reactive oxygen species (ROS) and impairment of defensive antioxidant systems leads to a condition known as oxidative stress. The main source of free radicals responsible for oxidative stress is mitochondrial respiration. The deleterious effects of ROS on cellular biomolecules, including DNA, is a well-known phenomenon that can disrupt mitochondrial function and contribute to cellular damage and death, and the subsequent development of various disease processes. In this review, we summarize the most important findings that implicated mitochondrial oxidative stress in a wide variety of pathologies from Alzheimer disease (AD) to autoimmune type 1 diabetes. This review also discusses attempts to affect oxidative stress as a therapeutic avenue.

Protective Action of L. salivarius SGL03 and Lactoferrin against COVID-19 Infections in Human Nasopharynx.

In this study, we used live viral particles from oral secretions from 17 people infected with SARS-CoV-2 and from 17 healthy volunteers, which were plated on a suitable medium complete for all microorganisms and minimal for L.salivarius growth. Both types of media also contained an appropriately prepared vector system pGEM-5Zf (+) based on the lactose operon (beta-galactosidase system). Incubation was carried out on both types of media for 24 h with the addition of 200 µL of Salistat SGL03 solution in order to test its inhibitory effect on the coronavirus contained in the oral mucosa and nasopharynx, visible as light blue virus particles on the test plates, which gradually disappeared in the material collected from infected persons over time. Regardless of the conducted experiments, swabs were additionally taken from the nasopharynx of infected and healthy people after rinsing the throat and oral mucosa with Salistat SGL03. In both types of experiments, after 24 h of incubation on appropriate media with biological material, we did not find any virus particles. Results were also confirmed by MIC and MBC tests. Results prove that lactoferrin, as one of the ingredients of the preparation, is probably a factor that blocks the attachment of virus particles to the host cells, determining its anti-viral properties. The conducted preliminary experiments constitute a very promising model for further research on the anti-viral properties of the ingredients contained in the Salistat SGL03 dietary supplement.

Effect of Ligilactobacillus salivarius and Other Natural Components against Anaerobic Periodontal Bacteria.

In this present study, the bacteriostatic effect of Salistat SGL03 and the Lactobacillus salivarius strain contained in it was investigated in adults in in vivo and in vitro tests on selected red complex bacteria living in the subgingival plaque, inducing a disease called periodontitis, i.e., chronic periodontitis. Untreated periodontitis can lead to the destruction of the gums, root cementum, periodontium, and alveolar bone. Anaerobic bacteria, called periopathogens or periodontopathogens, play a key role in the etiopathogenesis of periodontitis. The most important periopathogens of the oral microbiota are: Porphyromonas gingivalis, Tannerella forsythia, Treponema denticola and others. Our hypothesis was verified by taking swabs of scrapings from the surface of the teeth of female hygienists (volunteers) on full and selective growth media for L. salivarius. The sizes of the zones of growth inhibition of periopathogens on the media were measured before (in vitro) and after consumption (in vivo) of Salistat SGL03, based on the disk diffusion method, which is one of the methods of testing antibiotic resistance and drug susceptibility of pathogenic microorganisms. Additionally, each of the periopathogens analyzed by the reduction inoculation method, was treated with L. salivarius contained in the SGL03 preparation and incubated together in Petri dishes. The bacteriostatic activity of SGL03 preparation in selected periopathogens was also analyzed using the minimum inhibition concentration (MIC) and minimum bactericidal concentration (MBC) tests. The obtained results suggest the possibility of using the Salistat SGL03 dietary supplement in the prophylaxis and support of the treatment of periodontitis-already treated as a civilization disease.

Maternal high-protein diet during pregnancy, but not during suckling, induced altered expression of an increasing number of hepatic genes in adult mouse offspring.

PURPOSE: Indirect effects of a high-protein maternal diet are not well understood. In this study, we analyzed short-term and sustainable effects of a prenatal versus early postnatal maternal high-protein diet on growth and hepatic gene expression in mouse offspring. METHODS: Dams were exposed to an isoenergetic high-protein (HP, 40 % w/w) diet during pregnancy or lactation. Growth and hepatic expression profiles of male offspring were evaluated directly after weaning and 150 days after birth. Offspring from two dietary groups, high-protein diet during pregnancy and control diet during lactation (HPC), and control diet during pregnancy and high-protein diet during lactation (CHP), were compared with offspring (CC) from control-fed dams. RESULTS: Maternal CHP treatment was associated with sustained offspring growth retardation, but decreased numbers of affected hepatic genes in adults compared to weanlings. In contrast, offspring of the HPC group did not show persistent effects on growth parameters, but the number of affected hepatic genes was even increased at adult age. In both dietary groups, however, only a small subset of genes was affected in weanlings as well as in adults. CONCLUSIONS: We conclude that (1) prenatal and early postnatal maternal HP diet caused persistent, but (2) different effects and partially complementary trends on growth characteristics and on the hepatic transcriptome and associated pathways and that (3) only a small number of genes and associated upstream regulators might be involved in passing early diet-induced imprints to adulthood.

Enhanced sensitivity of skeletal muscle growth in offspring of mice long-term selected for high body mass in response to a maternal high-protein/low-carbohydrate diet during lactation.

AIM: To investigate the effects of a high-protein/low-carbohydrate diet fed to mice of different genotypes during pregnancy and/or lactation on offspring skeletal muscle growth and metabolism. METHODS: Pregnant mice from strains selected for high body mass (DU6) or endurance running performance (DUhLB) and from an unselected control strain (DUK) were fed iso-energetic diets containing 20 % (C) or 40 % protein and low carbohydrate (HP) from mating to weaning at day 21 of age. At birth, offspring were cross-fostered resulting in different exposure to maternal prenatal-preweaning diets (C-C, HP-C, C-HP, HP-HP). Rectus femoris muscle of male mice (n = 291) was examined at day 23, 44, 181 and 396 of age for cellular growth and metabolism. RESULTS: At day 23 of age, body and muscle growth was retarded by 30-40 % (P < 0.0001) in response to the C-HP and HP-HP, but not to the HP-C diet, due to reduced fibre size (P < 0.0001) but not fibre number. DNA was highly reduced in DU6, less in DUhLB, but not in DUK muscle (strain × diet; P < 0.0001). Despite some compensation, muscle growth was still impaired (P < 0.001) in adulthood (day 44; day 181), but at senescence only in DU6 mice (strain × diet; P < 0.05). Only at weaning, isocitrate and lactate dehydrogenase activities were increased or decreased (P < 0.0001), respectively, without influence on fibre type composition. CONCLUSION: A high-protein/low-carbohydrate diet fed to dams during lactation, but not during pregnancy, retards skeletal muscle growth in offspring with greater response of a heavy, obese compared with a physically fit and a control genotype and causes a transient shift towards oxidative versus glycolytic muscle metabolism.

High-protein diet in lactation leads to a sudden infant death-like syndrome in mice.

BACKGROUND: It is well accepted that reduced foetal growth and development resulting from maternal malnutrition are associated with a number of chronic conditions in later life. On the other hand such generation-transcending effects of over-nutrition and of high-protein consumption in pregnancy and lactation, a proven fact in all developed societies, are widely unknown. Thus, we intended to describe the generation-transcending effects of a high-protein diet, covering most relevant topics of human life like embryonic mortality, infant death, and physical health in later life. METHODS: Female mice received control food (21% protein) or were fed a high protein diet (42% protein) during mating. After fertilisation, females stayed on their respective diet until weaning. At birth, pups were put to foster mothers who were fed with standard food or with HP diet. After weaning, control diet was fed to all mice. All offspring were monitored up to 360 days after birth. We determined glucose-tolerance and measured cardiovascular parameters using a tip-catheter. Finally, abdominal fat amount was measured. RESULTS AND CONCLUSIONS: We identified a worried impact of high-protein diet during pregnancy on dams' body weight gain, body weight of newborns, number of offspring, and also survival in later life. Even more important is the discovery that high-protein diet during lactation caused a more than eight-fold increase in offspring mortality. The observed higher newborn mortality during lactation is a hitherto non-described, unique link to the still incompletely understood human sudden infant death syndrome (SIDS). Thus, although offspring of lactating mothers on high-protein diet might have the advantage of lower abdominal fat within the second half of life, this benefit seems not to compensate the immense risk of an early sudden death during lactation. Our data may implicate that both pregnant women and lactating mothers should not follow classical high-protein diets.

Hepatic expression of the GH/JAK/STAT/IGF pathway, acute-phase response signalling and complement system are affected in mouse offspring by prenatal and early postnatal exposure to maternal high-protein diet.

PURPOSE: Effects of pre- and early postnatal exposure to maternal high-protein diets are not well understood. Transcription profiling was performed in male mouse offspring exposed to maternal high-protein diet during pregnancy and/or lactation to identify affected hepatic molecular pathways. METHODS: Dams were fed isoenergetic diets with control (20% w/w) or high protein levels (40%). The hepatic expression profiles were evaluated by differential microarray analysis 3 days (d3) and 3 weeks (d21) after birth. Offspring from three different high-protein dietary groups, HP (d3, high-protein diet during pregnancy), HPHP (d21, high-protein diet during pregnancy and lactation) and CHP (d21, control diet during pregnancy and high-protein diet during lactation), were compared with age-matched offspring from dams fed control diet. RESULTS: Offspring body and liver mass of all high-protein groups were decreased. Prenatal high-protein diet affected hepatic expression of genes mapping to the acute response/complement system and the GH/JAK/STAT/IGF signalling pathways. Maternal exposure to high-protein diet during lactation affected hepatic gene expression of the same pathways but additionally affected genes mapping to protein, fatty acid, hexose and pyruvate metabolism. CONCLUSIONS: (1) Genes of the acute response/complement system and GH/JAK/STAT/IGF pathways were down-regulated in offspring of dams exposed to high-protein diets during pregnancy and/or lactation. (2) Genes related to nutrient and energy metabolism, however, were only affected when high-protein diet was administered during lactation. (3) Modulation of the GH/JAK/STAT/IGF pathway might be responsible for reduced body and liver masses by maternal high-protein diet.

Effect of a high-protein diet on food intake and liver metabolism during pregnancy, lactation and after weaning in mice.

Major hepatic metabolic pathways are involved in the control of food intake but how dietary proteins affect global metabolism to adjust food intake is incompletely understood, particularly under physiological challenging conditions such as lactation. In order to identify these molecular events, mice were fed a high-protein (HP) diet from pregnancy, during lactation until after weaning and compared with control fed counterparts. Liver specimens were analyzed for regulated proteins using 2-DE and MALDI-TOF-MS and plasma samples for metabolites. Based on the 26 differentially expressed proteins associated with depleted liver glycogen content, elevated urea and citrulline plasma concentrations, we conclude that HP feeding during lactation leads to an activated amino acid, carbohydrate and fatty acid catabolism while it activates gluconeogenesis. From pregnancy to lactation, plasma arginine, tryptophan, serine, glutamine and cysteine decreased, whereas urea concentrations increased in both groups. Concomitantly, hepatic glycogen content decreased while total fat content remained unaltered in both groups. Consideration of 59 proteins differentially expressed between pregnancy and lactation highlights different strategies of HP and control fed mice to meet energy requirements for lactation by adjusting amino acid degradation, carbohydrate and fat metabolism, citrate cycle, but also ATP-turnover, protein folding, secretion of proteins and (de)activation of transcription factors.

[Helminth fauna of rodents (Arvicolidae and Muridae) from the Kampinos National Park]. / Helmintofauna przewodu pokarmowego gryzoni (Rodentia: Arvicolidae i Muridae) z Kampinoskiego Parku Narodowego.

BACKGROUND: The aim of the study was to examine the parasite fauna of rodents living in natural environment, but in close contact with human seats (small village at the area of the natural big forest). MATERIAL AND METHODS: 169 rodents from family Arvicolidae and Muridae were examined. The material comprised: Microtus arvalis--5 specimens, Mus musculus--131, Apodemus silvaticus--9, Apodemus flavicollis--8, Apodemus agrarius--14 and Micromys minutus--2 specimens, collected between April 2003 and July 2004. RESULTS: The examination of some internal organs (alimentary tract, liver, lungs, kidneys, heart, body cavity) revealed the occurence of 8 helminth species: 3 species of Cestoda (Paranoplocephala macrocephala, Hymenolepis diminuta, Taenia taeniaeformis) and 5 species of Nematoda (Heterakis spumosa, Aspiculuris tetraptera, Syphacia obvelata, Heligmosomoides polygyrum, Mastophorus muris), all in the alimentary tract (including liver). The helminth fauna of every rodent species was determined, as well as seasonal dynamics of their frequency. It was stated that only the species which realize the complex life cycle undergo some seasonal fluctuations of their abundance. Additionally the distribution of particular helminth species along the alimentary tract of their hosts was described.