Reconsidering the relation between serum homocysteine and red blood cell distribution width: a cross-sectional study of a large cohort

Purpose: In a recent small sample study, red blood cell distribution width (RDW) was suggested as a predictor of homocysteine levels. The current study was aimed to reexamine this association in a large scale sample.

Methods: A retrospective cross-sectional study of healthy adults, conducted at Rabin Medical Center, during 2000–2014. Data were retrieved from the medical charts and a logistic regression controlling for interfering factors was carried out. Sensitivity analysis was implemented by exclusion of individuals with anaemia.

Results: Five thousand, five hundred fifty-four healthy individuals were included. Mean serum homocysteine level was 10.10 (SD 2.72) μmol/L. 34.4% of the study population had a homocysteine level higher than the upper limit of normal (10.8?μmol/L). Homocysteine showed no association with RDW (OR 1.00; 95% CI 0.97–1.03), but increased with age (OR 1.05; 95% CI 1.04–1.06) and decreased with a rise in haemoglobin (OR 0.77; 95% CI 0.71–0.83), and in the mean corpuscular volume (OR 0.86; 95% CI 0.85–0.88). Exclusion of individuals with anaemia did not reveal an association between homocysteine and RDW but found a somewhat smaller association between haemoglobin and RDW [OR 0.82; 95% CI 0.73–0.91].

Conclusions: In our large scale sample we did not find an association between RDW and serum homocysteine.     

Biogenesis of chloroplast membranes: XIV. Inhomogeneity of membrane protein distribution in photosystem particles obtained from Chlamydomonas reinhardi. Y-l

Treatment of chloroplast membranes of Chlamydomonas reinhardi with Triton-× 100 yielded membrane particles which were resolved into three bands on discontinuous sucrose gradients. One of these was enriched in the chlorophyll absorption and fluorescence properties and photosynthetic activities consistent with photosystem I enrichment, while another had the chlorophyll absorption and fluorescence properties expected to photosystem II enriched particles. The third type of particle was enriched in chlorophyll species which are probably the bulk chlorophylls of photosystem I. Analysis of the proteins of these fractions by polyacrylamide electrophoresis indicated substantial differences, the most striking being that the photosystem II particle type was greatly enriched in the major species of chloroplast membrane protein. Previous work has shown this to be an important protein controlling membrane assembly. This protein was depleted in the photosystem I particle type. We interpret this data to indicate a lack of homogeneity in the distribution of membrane proteins in the chloroplast membranes of Chlamydomonas, at the level of the two photosystems.     

A new lysozyme from the eastern oyster, <Emphasis Type="Italic">Crassostrea virginica</Emphasis>, and a possible evolutionary pathway for i-type lysozymes in bivalves from host defense to digestion

Background  

Lysozymes are enzymes that lyse bacterial cell walls, an activity widely used for host defense but also modified in some instances for digestion. The biochemical and evolutionary changes between these different functional forms has been well-studied in the c-type lysozymes of vertebrates, but less so in the i-type lysozymes prevalent in most invertebrate animals. Some bivalve molluscs possess both defensive and digestive lysozymes.     

A Novel Nutritional Predictor Links Microbial Fastidiousness with Lowered Ubiquity,Growth Rate,and Cooperativeness

Understanding microbial nutritional requirements is a key challenge in microbiology. Here we leverage the recent availability of thousands of automatically generated genome-scale metabolic models to develop a predictor of microbial minimal medium requirements, which we apply to thousands of species to study the relationship between their nutritional requirements and their ecological and genomic traits. We first show that nutritional requirements are more similar among species that co-habit many ecological niches. We then reveal three fundamental characteristics of microbial fastidiousness (i.e., complex and specific nutritional requirements): (1) more fastidious microorganisms tend to be more ecologically limited; (2) fastidiousness is positively associated with smaller genomes and smaller metabolic networks; and (3) more fastidious species grow more slowly and have less ability to cooperate with other species than more metabolically versatile organisms. These associations reflect the adaptation of fastidious microorganisms to unique niches with few cohabitating species. They also explain how non-fastidious species inhabit many ecological niches with high abundance rates. Taken together, these results advance our understanding microbial nutrition on a large scale, by presenting new nutrition-related associations that govern the distribution of microorganisms in nature.     

Maximal Sum of Metabolic Exchange Fluxes Outperforms Biomass Yield as a Predictor of Growth Rate of Microorganisms

Growth rate has long been considered one of the most valuable phenotypes that can be measured in cells. Aside from being highly accessible and informative in laboratory cultures, maximal growth rate is often a prime determinant of cellular fitness, and predicting phenotypes that underlie fitness is key to both understanding and manipulating life. Despite this, current methods for predicting microbial fitness typically focus on yields [e.g., predictions of biomass yield using GEnome-scale metabolic Models (GEMs)] or notably require many empirical kinetic constants or substrate uptake rates, which render these methods ineffective in cases where fitness derives most directly from growth rate. Here we present a new method for predicting cellular growth rate, termed SUMEX, which does not require any empirical variables apart from a metabolic network (i.e., a GEM) and the growth medium. SUMEX is calculated by maximizing the SUM of molar EXchange fluxes (hence SUMEX) in a genome-scale metabolic model. SUMEX successfully predicts relative microbial growth rates across species, environments, and genetic conditions, outperforming traditional cellular objectives (most notably, the convention assuming biomass maximization). The success of SUMEX suggests that the ability of a cell to catabolize substrates and produce a strong proton gradient enables fast cell growth. Easily applicable heuristics for predicting growth rate, such as what we demonstrate with SUMEX, may contribute to numerous medical and biotechnological goals, ranging from the engineering of faster-growing industrial strains, modeling of mixed ecological communities, and the inhibition of cancer growth.     

Synthetic lethality-mediated precision oncology via the tumor transcriptome

1. Download : Download high-res image (274KB)
2. Download : Download full-size image