On How Many Fundamental Kinds of Cells are Present on Earth: Looking for Phylogenetic Traits that Would Allow the Identification of the Primary Lines of Descent

The phylogenetic analyses as far as the identification of the number of domains of life is concerned have not reached a clear conclusion. In the attempt to improve this circumstance, I introduce the concept that the amino acids codified in the genetic code might be of markers with outstanding phylogenetic power. In particular, I hypothesise the existence of a biosphere populated, for instance, by three groups of organisms having different genetic codes because codifying at least a different amino acid. Evidently, these amino acids would mark the proteins that are present in the three groups of organisms in an unambiguous way. Therefore, in essence, this mark would not be other than the one that we usually try to make in the phylogenetic analyses in which we transform the protein sequences in phylogenetic trees, for the purpose to identify, for example, the domains of life. Indeed, this mark would allow to classify proteins without performing phylogenetic analyses because proteins belonging to a group of organisms would be recognisable as marked in a natural way by at least a different amino acid among the diverse groups of organisms. This conceptualisation answers the question of how many fundamental kinds of cells have evolved from the Last Universal Common Ancestor (LUCA), as the genetic code has unique proprieties that make the codified amino acids excellent phylogenetic markers. The presence of the formyl-methionine only in proteins of bacteria would mark them and would identify these as domain of life. On the other hand, the presence of pyrrolysine in the genetic code of the euryarchaeota would identify them such as another fundamental kind of cell evolved from the LUCA. Overall, the phylogenetic distribution of formyl-methionine and pyrrolysine would identify at least two domains of life—Bacteria and Archaea—but their number might be actually four; that is to say, Bacteria, Euryarchaeota, archeobacteria that are not euryarchaeota and Eukarya. The usually accepted domains of life represented by Bacteria, Archaea and Eukarya are not compatible with the phylogenetic distribution of these two amino acids and therefore this last classification might be mistaken.     

The urokinase‐type plasminogen activator system as drug target in retinitis pigmentosa: New pre‐clinical evidence in the rd10 mouse model

Retinitis pigmentosa (RP) is characterized by progressive loss of vision due to photoreceptor degeneration leading to secondary inflammation. The urokinase‐type plasminogen activator (uPA) system contributes to retinal inflammation, but its role in RP is unknown. In the rd10 mouse model of RP, we addressed this question with the use of the peptide UPARANT designed to interact with the uPA system. UPARANT was systemically administered from post‐natal day (PD) 10 to PD30 when its efficacy in RP rescue was investigated using electroretinographic recordings, Western blot and immunocytochemistry. Temporal profile of protein expression in the uPA system was also investigated. UPARANT reduced both Müller cell gliosis and up‐regulated levels of inflammatory markers and exerted major anti‐apoptotic effects without influencing the autophagy cascade. Rescue from retinal cell degeneration was accompanied by improved retinal function. No scotopic phototransduction was rescued in the UPARANT‐treated animals as determined by the kinetic analysis of rod‐mediated a‐waves and confirmed by rod photoreceptor markers. In contrast, the cone photopic b‐wave was recovered and its rescue was confirmed in the whole mounts using cone arrestin antibody. Investigation of the uPA system regulation over RP progression revealed extremely low levels of uPA and its receptor uPAR both of which were recovered by HIF‐1α stabilization indicating that HIF‐1 regulates the expression of the uPA/uPAR gene in the retina. Ameliorative effects of UPARANT were likely to occur through an inhibitory action on up‐regulated activity of the αvβ3 integrin/Rac1 pathway that was suggested as a novel target for the development of therapeutic approaches against RP.     

A computational approach identifies two regions of Hepatitis C Virus E1 protein as interacting domains involved in viral fusion process

Background  

The E1 protein of Hepatitis C Virus (HCV) can be dissected into two distinct hydrophobic regions: a central domain containing an hypothetical fusion peptide (FP), and a C-terminal domain (CT) comprising two segments, a pre-anchor and a trans-membrane (TM) region. In the currently accepted model of the viral fusion process, the FP and the TM regions are considered to be closely juxtaposed in the post-fusion structure and their physical interaction cannot be excluded. In the present study, we took advantage of the natural sequence variability present among HCV strains to test, by purely sequence-based computational tools, the hypothesis that in this virus the fusion process involves the physical interaction of the FP and CT regions of E1.     

The Pharmacogenetic Footprint of ACE Inhibition: A Population-Based Metabolomics Study

Angiotensin-I-converting enzyme (ACE) inhibitors are an important class of antihypertensives whose action on the human organism is still not fully understood. Although it is known that ACE especially cleaves COOH-terminal dipeptides from active polypeptides, the whole range of substrates and products is still unknown. When analyzing the action of ACE inhibitors, effects of genetic variation on metabolism need to be considered since genetic variance in the ACE gene locus was found to be associated with ACE-concentration in blood as well as with changes in the metabolic profiles of a general population. To investigate the interactions between genetic variance at the ACE-locus and the influence of ACE-therapy on the metabolic status we analyzed 517 metabolites in 1,361 participants from the KORA F4 study. We replicated our results in 1,964 individuals from TwinsUK. We observed differences in the concentration of five dipeptides and three ratios of di- and oligopeptides between ACE inhibitor users and non-users that were genotype dependent. Such changes in the concentration affected major homozygotes, and to a lesser extent heterozygotes, while minor homozygotes showed no or only small changes in the metabolite status. Two of these resulting dipeptides, namely aspartylphenylalanine and phenylalanylserine, showed significant associations with blood pressure which qualifies them—and perhaps also the other dipeptides—as readouts of ACE-activity. Since so far ACE activity measurement is substrate specific due to the usage of only one oligopeptide, taking several dipeptides as potential products of ACE into account may provide a broader picture of the ACE activity.     

One-step reconstruction of multi-generation pedigree networks in apple (Malus × domestica Borkh.) and the parentage of Golden Delicious

The increasing availability of genomic tools improves our ability to investigate the patterns of genetic diversity and relatedness among individuals. The pedigrees of many apple cultivars are completely unknown, often reducing the efficiency of breeding programs. Using a multilocus simple sequence repeat dataset, we applied a novel multi-generation pedigree-network reconstruction procedure based on the software FRANz in a Malus × domestica collection (101 cultivated and 22 wild apples) with partially known pedigree relationships. The procedure produced 78 parent–offspring relationships organized into three networks and showed high power for detecting real pedigree links (98.5 %) and a low false-positive rate (9.0 %). The largest reconstructed pedigree network spanned four generations and involved 65 cultivars. The availability of detailed pedigree connections confirmed that recent genealogical relationships affect population genetic structure in apple. Finally, our analysis enabled us to confirm or discard several pedigrees known only anecdotically, among which the cultivar Grimes Golden was validated as a parent of the widely grown cultivar Golden Delicious. The pedigree reconstruction protocol here described will be of broad applicability to other collections and crop species.     

Hybrid-EKF: Hybrid model coupled with extended Kalman filter for real-time monitoring and control of mammalian cell culture

In a decade when Industry 4.0 and quality by design are major technology drivers of biopharma, automated and adaptive process monitoring and control are inevitable requirements and model-based solutions are key enablers in fulfilling these goals. Despite strong advancement in process digitalization, in most cases, the generated datasets are not sufficient for relying on purely data-driven methods, whereas the underlying complex bioprocesses are still not completely understood. In this regard, hybrid models are emerging as a timely pragmatic solution to synergistically combine available process data and mechanistic understanding. In this study, we show a novel application of the hybrid-EKF framework, that is, hybrid models coupled with an extended Kalman filter for real-time monitoring, control, and automated decision-making in mammalian cell culture processing. We show that, in the considered application, the predictive monitoring accuracy of such a framework improves by at least 35% when developed with hybrid models with respect to industrial benchmark tools based on PLS models. In addition, we also highlight the advantages of this approach in industrial applications related to conditional process feeding and process monitoring. With regard to the latter, for an industrial use case, we demonstrate that the application of hybrid-EKF as a soft sensor for titer shows a 50% improvement in prediction accuracy compared with state-of-the-art soft sensor tools.     

Characterisation of RC-proteoliposomes at different RC/lipid ratios

Reconstitution of membrane proteins in phospholipid vesicles allows the investigation of such macromolecules in a biomimetic simplified environment. The often employed micelle-to-vesicle-transition method for proteoliposome preparation is a fast and reproducible technique. In this, communication is shown that the lipid/protein ratio influences the size of the proteoliposomes and the actual protein reconstitution. The results indicate that for photosynthetic reaction centres, the best conditions for ligand-interaction experiments are achieved with a lipid/protein value of 1000:1, while for complete protein incorporation, the 2000:1 ratio should be chosen.     

Influence of different levels of ammonium concentrations on cell growth,RNA and protein production byCandida albicans

Candida albicans starved cells were incubated in minimal synthetic liquid media containing different concentrations of ammonium sulphate (0.00, 0.02, 0.05, 0.10, 0.03, 0.50 g/L). Culture growth was monitored by measuring daily the optical density and by evaluating RNA and protein cellular content after 48 and 96 hours from the inoculum. The environmental availability of ammonium ion influenced the biomass production, that was maximum when its concentration was 0.10 and 0.30 g/L. In addition, an effect on cell duplication time was observed, this was particularly evident when the (NH₄)₂SO₄ concentration was 0.10 g/L. The protein content increased in relation to the increase of ammonium ion availability, with a peak in correspondence to 0.30 g/L and a drop when the greatest concentrations were employed. RNA production was inversely proportional in respect to protein production. The optimal range of ammonium sulphate concentration forC. albicans growth was 0.10–0.30 g/L; over these concentrations there was an inhibitory effect. The rate of the protein and RNA syntheses seems to indicate the growth phase and the nitrogen nutritional conditions of the cultures, respectively.