Evolution and self-assembly of protocells

Cells define the minimal building blocks of life. How cellular life emerged and evolved implies to cross the boundary between living and nonliving matter. Here we explore this problem by presenting several relevant components of the whole picture involving chemistry, physics and natural selection. Available evidence suggests that the basic logic of life can be understood and eventually translated into synthetic forms of cellular life. A simple, physically sound model of information-free protocell replication suggests that the basic logic of how to couple metabolism and container can be more relevant than the specific set of parameters used, thus indicating that the emergence of cells might have been easier than we would expect.     

In vitro recombination of non-homologous genes can result in gene fusions that confer a switching phenotype to cells

Regulation of protein activity is central to the complexity of life. The ability to regulate protein activity through exogenously added molecules has biotechnological/biomedical applications and offers tools for basic science. Such regulation can be achieved by establishing a means to modulate the specific activity of the protein (i.e. allostery). An alternative strategy for intracellular regulation of protein activity is to control the amount of protein through effects on its production, accumulation, and degradation. We have previously demonstrated that the non-homologous recombination of the genes encoding maltose binding protein (MBP) and TEM1 β-lactamase (BLA) can result in fusion proteins in which β-lactamase enzyme activity is allosterically regulated by maltose. Here, through use of a two-tiered genetic selection scheme, we demonstrate that such recombination can result in genes that confer maltose-dependent resistance to β-lactam even though they do not encode allosteric enzymes. These 'phenotypic switch' genes encode fusion proteins whose accumulation is a result of a specific interaction with maltose. Phenotypic switches represent an important class of proteins for basic science and biotechnological applications in vivo.     

Horizontal gene transfer and the rock record: comparative genomics of phylogenetically distant bacteria that induce wrinkle structure formation in modern sediments

Wrinkle structures are sedimentary features that are produced primarily through the trapping and binding of siliciclastic sediments by mat‐forming micro‐organisms. Wrinkle structures and related sedimentary structures in the rock record are commonly interpreted to represent the stabilizing influence of cyanobacteria on sediments because cyanobacteria are known to produce similar textures and structures in modern tidal flat settings. However, other extant bacteria such as filamentous representatives of the family Beggiatoaceae can also interact with sediments to produce sedimentary features that morphologically resemble many of those associated with cyanobacteria‐dominated mats. While Beggiatoa spp. and cyanobacteria are metabolically and phylogenetically distant, genomic analyses show that the two groups share hundreds of homologous genes, likely as the result of horizontal gene transfer. The comparative genomics results described here suggest that some horizontally transferred genes may code for phenotypic traits such as filament formation, chemotaxis, and the production of extracellular polymeric substances that potentially underlie the similar biostabilizing influences of these organisms on sediments. We suggest that the ecological utility of certain basic life modes such as the construction of mats and biofilms, coupled with the lateral mobility of genes in the microbial world, introduces an element of uncertainty into the inference of specific phylogenetic origins from gross morphological features preserved in the ancient rock record.     

MitoNuc: a database of nuclear genes coding for mitochondrial proteins. Update 2002

Mitochondria, besides their central role in energy metabolism, have recently been found to be involved in a number of basic processes of cell life and to contribute to the pathogenesis of many degenerative diseases. All functions of mitochondria depend on the interaction of nuclear and organelle genomes. Mitochondrial genomes have been extensively sequenced and analysed and data have been collected in several specialised databases. In order to collect information on nuclear coded mitochondrial proteins we developed MitoNuc, a database containing detailed information on sequenced nuclear genes coding for mitochondrial proteins in Metazoa. The MitoNuc database can be retrieved through SRS and is available via the web site http://bighost.area.ba.cnr.it/mitochondriome where other mitochondrial databases developed by our group, the complete list of the sequenced mitochondrial genomes, links to other mitochondrial sites and related information, are available. The MitoAln database, related to MitoNuc in the previous release, reporting the multiple alignments of the relevant homologous protein coding regions, is no longer supported in the present release. In order to keep the links among entries in MitoNuc from homologous proteins, a new field in the database has been defined: the cluster identifier, an alpha numeric code used to identify each cluster of homologous proteins. A comment field derived from the corresponding SWISS-PROT entry has been introduced; this reports clinical data related to dysfunction of the protein. The logic scheme of MitoNuc database has been implemented in the ORACLE DBMS. This will allow the end-users to retrieve data through a friendly interface that will be soon implemented.     

Detection of horizontal transfer of individual genes by anomalous oligomer frequencies

ABSTRACT: BACKGROUND: Understanding the history of life requires that we understand the transfer of genetic materialacross phylogenetic boundaries. Detecting genes that were acquired by means other thanvertical descent is a basic step in that process. Detection by discordant phylogenies iscomputationally expensive and not always definitive. Many have used easily computedcompositional features as an alternative procedure. However, different compositionalmethods produce different predictions, and the effectiveness of any method is not wellestablished. RESULTS: The ability of octamer frequency comparisons to detect genes artificially seeded incyanobacterial genomes was markedly increased by using as a training set those genes thatare highly conserved over all bacteria. Using a subset of octamer frequencies in such testsalso increased effectiveness, but this depended on the specific target genome and the sourceof the contaminating genes. The presence of high frequency octamers and the GC content ofthe contaminating genes were important considerations. A method comprising best practicesfrom these tests was devised, the Core Gene Similarity (CGS) method, and it performedbetter than simple octamer frequency analysis, codon bias, or GC contrasts in detectingseeded genes or naturally occurring transposons. From a comparison of predictions withphylogenetic trees, it appears that the effectiveness of the method is confined to horizontaltransfer events that have occurred recently in evolutionary time. CONCLUSIONS: The CGS method may be an improvement over existing surrogate methods to detect genes offoreign origin.     

Endless versatility in the biotechnological applications of Kluyveromyces LAC genes

Most microorganisms adapted to life in milk owe their ability to thrive in this habitat to the evolution of mechanisms for the use of the most abundant sugar present on it, lactose, as a carbon source. Because of their lactose-assimilating ability, Kluyveromyces yeasts have long been used in industrial processes involved in the elimination of this sugar. The identification of the genes conferring Kluyveromyces with a system for permeabilization and intracellular hydrolysis of lactose (LAC genes), along with the current possibilities for their transfer into alternative organisms through genetic engineering, has significantly broadened the industrial profitability of lactic yeasts. This review provides an updated overview of the general properties of Kluyveromyces LAC genes, and the multiple techniques involving their biotechnological utilization. Emphasis is also made on the potential that some of the latest technologies, such as the generation of transgenics, will have for a further benefit in the use of these and related genes.     

A new generation of antibodies

Antibodies, proteins produced in animals that bind with high specificity and affinity to a seemingly limitless variety of biomolecules, have an essential role in clinical medicine and basic biological research. Methods to produce antibody fragments on the surface of bacterial viruses were surveyed for their ability to replace animal-dependent antibodies. The use of filamentous phage to display antibody fragments derived from semisynthetic antibody genes was found to produce proteins that bind to antigens with a variety, specificity, and affinity similar to those produced in animal systems.     

The making of a flower: control of floral meristem identity in IT>Arabidopsis/IT>

During the reproductive phase of a plant, shoot meristems follow one of two developmental programs to produce either flowers or vegetative shoots. The decision as to which meristems give rise to flowers, and when they do so, determines the general morphology of an inflorescence. Molecular and genetic research in Arabidopsis and other model species has identified several genes that control the identity that a meristem will adopt. These meristem identity genes are activated in response to developmental and environmental cues, and can be assigned to three basic categories: those required either to initiate or maintain the floral program in some meristems and those required to maintain the vegetative program in others.     

Embryonic mutants of Arabidopsis thaliana

Genetic analysis of plant em-bryogenesis has been approached in part through the isolation and characterization of recessive embryonic mutants. The most extensive studies have dealt with maize and Arabidopsis. The high frequency of mutants defective in plant embryogenesis is consistent with the presence of many target genes with essential functions at this stage of the life cycle. Some mutants are likely to be defective in genes with general housekeeping functions. Others should facilitate the identification of genes with a more direct role in the regulation of morphogesis. Over 300 embryonic mutants of Arabidopsis isolated following chemical mutagenesis and T-DNA insertional mutagenesis are currently being analyzed. This collection includes embryonic le-thals, defectives, and pattern mutants. Developmental abnormalities include the presence of fused cotyledons, twin embryos, abnormally large suspensors, distorted epidermal layers, single cotyledons, enlarged shoot apices, pattern deletions and duplications, embryos with altered patterns of symmetry, bloated embryos with giant vacuolated cells, reduced hypocotyls that fail to produce roots, and embryos that protrude through the seed coat late in maturation. This review describes the isolation and characterization of embryonic mutants of Arabidopsis and their potential application to plant biology. © 1992 Wiley-Liss, Inc.     

The roles of intrinsic and extrinsic cues and bHLH genes in the determination of retinal cell fates

A fundamental issue concerning development of the vertebrate retina is the relative contributions of extrinsic and intrinsic cues to the determination of cell fate. Recent findings suggest that retinal progenitors go through a series of changes in intrinsic properties that control their competence to make different cell types and that extrinsic cues influence the ratios of the cell types that they produce. Recent studies of the role of the basic helix-loop-helix genes in retinal development have indicated that they can regulate competence and/or other aspects of cell fate determination.     

Physical anthropology,peace and justice: Some observations

Human biological well being is a concern of physical anthropology. Genetic determinants and also sociocultural factors, which operate through biological bases, affect human biological quality. Several populations from different parts of the globe have been identified where varieties of detrimental genes occur in considerable numbers influencing health and some other related biological aspects of human life. Injustice will be done to those populations if necessary measures are not undertaken to improve their biological qualities. Peace cannot prevail in an atmosphere where people are deprived of the basic amenities for survival and maintenance of good health.     

A whole-genome RNAi Screen for C. elegans miRNA pathway genes

BACKGROUND: miRNAs are an abundant class of small, endogenous regulatory RNAs. Although it is now appreciated that miRNAs are involved in a broad range of biological processes, relatively little is known about the actual mechanism by which miRNAs downregulate target gene expression. An exploration of which protein cofactors are necessary for a miRNA to downregulate a target gene should reveal more fully the molecular mechanisms by which miRNAs are processed, trafficked, and regulate their target genes. RESULTS: A weak allele of the C. elegans miRNA gene let-7 was used as a sensitized genetic background for a whole-genome RNAi screen to detect miRNA pathway genes, and 213 candidate miRNA pathway genes were identified. About 2/3 of the 61 candidates with the strongest phenotype were validated through genetic tests examining the dependence of the let-7 phenotype on target genes known to function in the let-7 pathway. Biochemical tests for let-7 miRNA production place the function of nearly all of these new miRNA pathway genes downstream of let-7 expression and processing. By monitoring the downregulation of the protein product of the lin-14 mRNA, which is the target of the lin-4 miRNA, we have identified 19 general miRNA pathway genes. CONCLUSIONS: The 213 candidate miRNA pathway genes identified could act at steps that produce and traffic miRNAs or in downstream steps that detect miRNA::mRNA duplexes to regulate mRNA translation. The 19 validated general miRNA pathway genes are good candidates for genes that may define protein cofactors for sorting or targeting miRNA::mRNA duplexes, or for recognizing the miRNA base-paired to the target mRNA to downregulate translation.     

Golden Rice and ‘Golden’ crops for human nutrition

Micronutrients are essential for a healthy life. Humans do not produce micronutrients, and hence they must obtain them through the foodchain. Staple crops are the predominant food source of mankind, but need to be complemented by other foodstuffs because they are generally deficient in one or the other micronutrient. Breeding for micronutrient-dense crops is not always a viable option because of the absence of genetic variability for the desired trait. Moreover, sterility issues and the complex genetic makeup of some crop plants make them unamenable to conventional breeding. In these cases, genetic modification remains the only viable option. The tools to produce a number of micronutrients in staple crops have recently become available thanks to the identification of the genes involved in the corresponding biochemical pathways at an unprecedented rate. Discarding genetic modification as a viable option is definitely not in the interest of human wellbeing.     

Evolutionary dynamics of invasion and escape

Whenever life wants to invade a new habitat or escape from a lethal selection pressure, some mutations may be necessary to yield sustainable replication. We imagine situations like (i) a parasite infecting a new host, (ii) a species trying to invade a new ecological niche, (iii) cancer cells escaping from chemotherapy, (iv) viruses or microbes evading anti-microbial therapy, and also (v) the repeated attempts of combinatorial chemistry in the very beginning of life to produce self-replicating molecules. All such seemingly unrelated situations have a common structure in terms of Darwinian dynamics: a replicator with a basic reproductive ratio less than one attempts to find some mutations that allow indefinite survival. We develop a general theory, based on multitype branching processes, to describe the evolutionary dynamics of invasion and escape.     

Enzymes are enriched in bacterial essential genes

Essential genes, those indispensable for the survival of an organism, play a key role in the emerging field, synthetic biology. Characterization of functions encoded by essential genes not only has important practical implications, such as in identifying antibiotic drug targets, but can also enhance our understanding of basic biology, such as functions needed to support cellular life. Enzymes are critical for almost all cellular activities. However, essential genes have not been systematically examined from the aspect of enzymes and the chemical reactions that they catalyze. Here, by comprehensively analyzing essential genes in 14 bacterial genomes in which large-scale gene essentiality screens have been performed, we found that enzymes are enriched in essential genes. Essential enzymes have overrepresented ligases (especially those forming carbon-oxygen bonds and carbon-nitrogen bonds), nucleotidyltransferases and phosphotransferases, while have underrepresented oxidoreductases. Furthermore, essential enzymes tend to associate with more gene ontology domains. These results, from the aspect of chemical reactions, provide further insights into the understanding of functions needed to support natural cellular life, as well as synthetic cells, and provide additional parameters that can be integrated into gene essentiality prediction algorithms.