A very brief note on why bacterial evolution has physiology.

The majority of bacteria live and evolve in surface biofilms. Both growth in biofilms and horizontal transfer of DNA are regulated by quorum-sensing pheromone signals. The common regulation of bacterial surface growth and DNA transfers illustrates how physiology contributes to bacterial evolution.

What we have learned about evolutionary genome change in the past 7 decades.

Cytogenetics and genomics have completely transformed our understanding of evolutionary genome change since the early 1950s. The point of this paper is to outline some of the empirical findings responsible for that transformation. The discovery of transposable elements (TEs) in maize by McClintock, and their subsequent rediscovery in all forms of life, tell us that organisms have the inherent capacity to evolve dispersed genomic networks encoding complex cellular and multicellular adaptations. Genomic analysis confirms the role of TEs in wiring novel networks at major evolutionary transitions. TEs and other forms of repetitive DNA are also important contributors to genome regions that serve as transcriptional templates for regulatory and other biologically functional noncoding ncRNAs. The many functions documented for ncRNAs shows the concept of abundant "selfish" or "junk" DNA in complex genomes is mistaken. Natural and artificial speciation by interspecific hybridization demonstrates that TEs and other biochemical systems of genome restructuring are subject to rapid activation and can generate changes throughout the genomes of the novel species that emerge. In addition to TEs and hybrid species, cancer cells have taught us important lessons about chromothripsis, chromoplexy and other forms of non-random multisite genome restructuring. In many of these restructured genomes, alternative end-joining processes display the capacities of eukaryotes to generate novel combinations of templated and untemplated DNA sequences at the sites of break repair. Sequence innovation by alternative end-joining is widespread among eukaryotes from single cells to advanced plants and animals. In sum, the cellular and genomic capacities of eukaryotic cells have proven to be capable of executing rapid macroevolutionary change under a variety of conditions.

Repetitive DNA is Functional and Encodes Parts of the Non-Coding RNA Repertoire.

This is a commentary on the article by Eviatar Nevo and Kexin Li entitled "Sympatric Speciation in Mole Rats and Wild Barley and Their Genome Repeatome Evolution: A Commentary", published recently in Advanced Genetics.

How Chaotic Is Genome Chaos?

Cancer genomes evolve in a punctuated manner during tumor evolution. Abrupt genome restructuring at key steps in this evolution has been called "genome chaos." To answer whether widespread genome change is truly chaotic, this review (i) summarizes the limited number of cell and molecular systems that execute genome restructuring, (ii) describes the characteristic signatures of DNA changes that result from activity of those systems, and (iii) examines two cases where genome restructuring is determined to a significant degree by cell type or viral infection. The conclusion is that many restructured cancer genomes display sufficiently unchaotic signatures to identify the cellular systems responsible for major oncogenic transitions, thereby identifying possible targets for therapies to inhibit tumor progression to greater aggressiveness.

What can evolutionary biology learn from cancer biology?

Detecting and treating cancer effectively involves understanding the disease as one of somatic cell and tumor macroevolution. That understanding is key to avoid triggering an adverse reaction to therapy that generates an untreatable and deadly tumor population. Macroevolution differs from microevolution by karyotype changes rather than isolated localized mutations being the major source of hereditary variation. Cancer cells display major multi-site chromosome rearrangements that appear to have arisen in many different cases abruptly in the history of tumor evolution. These genome restructuring events help explain the punctuated macroevolutionary changes that mark major transitions in cancer progression. At least two different nonrandom patterns of rapid multisite genome restructuring - chromothripsis ("chromosome shattering") and chromoplexy ("chromosome weaving") - are clearly distinct in their distribution within the genome and in the cell biology of the stress-induced processes responsible for their occurrence. These observations tell us that eukaryotic cells have the capacity to reorganize their genomes rapidly in response to calamity. Since chromothripsis and chromoplexy have been identified in the human germline and in other eukaryotes, they provide a model for organismal macroevolution in response to the kinds of stresses that lead to mass extinctions.

All living cells are cognitive.

All living cells sense and respond to changes in external or internal conditions. Without that cognitive capacity, they could not obtain nutrition essential for growth, survive inevitable ecological changes, or correct accidents in the complex processes of reproduction. Wherever examined, even the smallest living cells (prokaryotes) display sophisticated regulatory networks establishing appropriate adaptations to stress conditions that maximize the probability of survival. Supposedly "simple" prokaryotic organisms also display remarkable capabilities for intercellular signalling and multicellular coordination. These observations indicate that all living cells are cognitive.

Why the third way of evolution is necessary.

The Third Way of Evolution was founded in 2014 to make the public aware that contemporary evolution science is not limited to the neo-Darwinian Modern Synthesis of the past century. This was important to do because evolution was challenged as incapable of explaining biological complexity by the Intelligent Design movement. Expounding biological theories like the Modern Synthesis is always subject to limited empirical evidence, fundamental concepts that inevitably change over time, and conceptual preferences that often prove to be misleading. The Modern Synthesis was based on Darwin's preference for the phyletic gradualism necessary to elevate Natural Selection as the sole force determining the direction of evolutionary change. In contradiction to this principle, agricultural crop breeding, direct observation in nature, and genomics have shown that genome change following symbiogenetic cell fusions or interspecific hybridization, not selection, are empirically the most effective methods for originating novel life forms and new species. By asserting that the accumulation of random "slight" variations was the basic mode of both short-term and long-term evolutionary change, the Modern Synthesis also ignored the distinction between (1) microevolutionary change within species by localized mutations and (2) macroevolutionary origination of new species and taxa by genome restructuring. In so doing, the Modern Synthesis failed to recognize the evolutionary importance of cellular capacities to generate large-scale genome changes. By focusing on individual protein-coding genes as the fundamental units of genetic information, the Modern Synthesis did not successfully incorporate either the full non-coding informa tion content in genomes or the major evolutionary potential of mobile DNA elements to generate multisite intragenomic networks necessary for the development of complex organisms. When all of the phenomena overlooked by the Modern Synthesis are taken into consideration, it is not difficult to answer Intelligent Design arguments and show that science is making real progress in understanding the evolution of biological complexity.

The active role of spermatozoa in transgenerational inheritance.

The active uptake of exogenous nucleic acids by spermatozoa of virtually all animal species is a well-established phenomenon whose significance has long been underappreciated. A growing body of published data demonstrates that extracellular vesicles released from mammalian somatic tissues pass an RNA-based flow of information to epididymal spermatozoa, thereby crossing the Weismann barrier. That information is delivered to oocytes at fertilization and affects the fate of the developing progeny. We propose that this essential process of epigenetic transmission depends upon the documented ability of epididymal spermatozoa to bind and internalize foreign nucleic acids in their nuclei. In other words, spermatozoa are not passive vectors of exogenous molecules but rather active participants in essential somatic communication across generations.

No genome is an island: toward a 21st century agenda for evolution.

Conventional 20th century evolution thinking was based on the idea of isolated genomes for each species. Any possibility of life-history inputs to the germ line was strictly excluded by Weismann's doctrine, and genome change was attributed to random copying errors. Today, we know that many life-history events lead to rapid and nonrandom evolutionary change mediated by specific cellular functions. There are many ways that genomes, viruses, cells, and organisms interact to generate evolutionary variation. These include cell mergers and activation of natural genetic engineering by stress, infection, and interspecific hybridization. In addition, we know molecular mechanisms for transmitting life-history information across generations through gametes. These discoveries require a new agenda for evolutionary theory and novel experimental designs to investigate the genomic impacts of stresses, biotic interactions, and sensory inputs coming from the environment. The review will offer some generic recommendations for enriching evolution experiments to incorporate new knowledge and find answers to previously excluded questions.

Single-cell analyses of human islet cells reveal de-differentiation signatures.

Human pancreatic islets containing insulin-secreting ß-cells are notoriously heterogeneous in cell composition. Since ß-cell failure is the root cause of diabetes, understanding this heterogeneity is of paramount importance. Recent reports have cataloged human islet transcriptome but not compared single ß-cells in detail. Here, we scrutinized ex vivo human islet cells from healthy donors and show that they exhibit de-differentiation signatures. Using single-cell gene expression and immunostaining analyses, we found healthy islet cells to contain polyhormonal transcripts, and INS+ cells to express decreased levels of ß-cell genes but high levels of progenitor markers. Rare cells that are doubly positive for progenitor markers/exocrine signatures, and endocrine/exocrine hormones were also present. We conclude that ex vivo human islet cells are plastic and can possibly de-/trans-differentiate across pancreatic cell fates, partly accounting for ß-cell functional decline once isolated. Therefore, stabilizing ß-cell identity upon isolation may improve its functionality.

Living Organisms Author Their Read-Write Genomes in Evolution.

Evolutionary variations generating phenotypic adaptations and novel taxa resulted from complex cellular activities altering genome content and expression: (i) Symbiogenetic cell mergers producing the mitochondrion-bearing ancestor of eukaryotes and chloroplast-bearing ancestors of photosynthetic eukaryotes; (ii) interspecific hybridizations and genome doublings generating new species and adaptive radiations of higher plants and animals; and, (iii) interspecific horizontal DNA transfer encoding virtually all of the cellular functions between organisms and their viruses in all domains of life. Consequently, assuming that evolutionary processes occur in isolated genomes of individual species has become an unrealistic abstraction. Adaptive variations also involved natural genetic engineering of mobile DNA elements to rewire regulatory networks. In the most highly evolved organisms, biological complexity scales with "non-coding" DNA content more closely than with protein-coding capacity. Coincidentally, we have learned how so-called "non-coding" RNAs that are rich in repetitive mobile DNA sequences are key regulators of complex phenotypes. Both biotic and abiotic ecological challenges serve as triggers for episodes of elevated genome change. The intersections of cell activities, biosphere interactions, horizontal DNA transfers, and non-random Read-Write genome modifications by natural genetic engineering provide a rich molecular and biological foundation for understanding how ecological disruptions can stimulate productive, often abrupt, evolutionary transformations.

Biological action in Read-Write genome evolution.

Many of the most important evolutionary variations that generated phenotypic adaptations and originated novel taxa resulted from complex cellular activities affecting genome content and expression. These activities included (i) the symbiogenetic cell merger that produced the mitochondrion-bearing ancestor of all extant eukaryotes, (ii) symbiogenetic cell mergers that produced chloroplast-bearing ancestors of photosynthetic eukaryotes, and (iii) interspecific hybridizations and genome doublings that generated new species and adaptive radiations of higher plants and animals. Adaptive variations also involved horizontal DNA transfers and natural genetic engineering by mobile DNA elements to rewire regulatory networks, such as those essential to viviparous reproduction in mammals. In the most highly evolved multicellular organisms, biological complexity scales with 'non-coding' DNA content rather than with protein-coding capacity in the genome. Coincidentally, 'non-coding' RNAs rich in repetitive mobile DNA sequences function as key regulators of complex adaptive phenotypes, such as stem cell pluripotency. The intersections of cell fusion activities, horizontal DNA transfers and natural genetic engineering of Read-Write genomes provide a rich molecular and biological foundation for understanding how ecological disruptions can stimulate productive, often abrupt, evolutionary transformations.

Exploring the read-write genome: mobile DNA and mammalian adaptation.

The read-write genome idea predicts that mobile DNA elements will act in evolution to generate adaptive changes in organismal DNA. This prediction was examined in the context of mammalian adaptations involving regulatory non-coding RNAs, viviparous reproduction, early embryonic and stem cell development, the nervous system, and innate immunity. The evidence shows that mobile elements have played specific and sometimes major roles in mammalian adaptive evolution by generating regulatory sites in the DNA and providing interaction motifs in non-coding RNA. Endogenous retroviruses and retrotransposons have been the predominant mobile elements in mammalian adaptive evolution, with the notable exception of bats, where DNA transposons are the major agents of RW genome inscriptions. A few examples of independent but convergent exaptation of mobile DNA elements for similar regulatory rewiring functions are noted.

Nothing in Evolution Makes Sense Except in the Light of Genomics: Read-Write Genome Evolution as an Active Biological Process.

The 21st century genomics-based analysis of evolutionary variation reveals a number of novel features impossible to predict when Dobzhansky and other evolutionary biologists formulated the neo-Darwinian Modern Synthesis in the middle of the last century. These include three distinct realms of cell evolution; symbiogenetic fusions forming eukaryotic cells with multiple genome compartments; horizontal organelle, virus and DNA transfers; functional organization of proteins as systems of interacting domains subject to rapid evolution by exon shuffling and exonization; distributed genome networks integrated by mobile repetitive regulatory signals; and regulation of multicellular development by non-coding lncRNAs containing repetitive sequence components. Rather than single gene traits, all phenotypes involve coordinated activity by multiple interacting cell molecules. Genomes contain abundant and functional repetitive components in addition to the unique coding sequences envisaged in the early days of molecular biology. Combinatorial coding, plus the biochemical abilities cells possess to rearrange DNA molecules, constitute a powerful toolbox for adaptive genome rewriting. That is, cells possess "Read-Write Genomes" they alter by numerous biochemical processes capable of rapidly restructuring cellular DNA molecules. Rather than viewing genome evolution as a series of accidental modifications, we can now study it as a complex biological process of active self-modification.

Sorcin Links Pancreatic ß-Cell Lipotoxicity to ER Ca2+ Stores.

Preserving ß-cell function during the development of obesity and insulin resistance would limit the worldwide epidemic of type 2 diabetes. Endoplasmic reticulum (ER) calcium (Ca(2+)) depletion induced by saturated free fatty acids and cytokines causes ß-cell ER stress and apoptosis, but the molecular mechanisms behind these phenomena are still poorly understood. Here, we demonstrate that palmitate-induced sorcin downregulation and subsequent increases in glucose-6-phosphatase catalytic subunit-2 (G6PC2) levels contribute to lipotoxicity. Sorcin is a calcium sensor protein involved in maintaining ER Ca(2+) by inhibiting ryanodine receptor activity and playing a role in terminating Ca(2+)-induced Ca(2+) release. G6PC2, a genome-wide association study gene associated with fasting blood glucose, is a negative regulator of glucose-stimulated insulin secretion (GSIS). High-fat feeding in mice and chronic exposure of human islets to palmitate decreases endogenous sorcin expression while levels of G6PC2 mRNA increase. Sorcin-null mice are glucose intolerant, with markedly impaired GSIS and increased expression of G6pc2 Under high-fat diet, mice overexpressing sorcin in the ß-cell display improved glucose tolerance, fasting blood glucose, and GSIS, whereas G6PC2 levels are decreased and cytosolic and ER Ca(2+) are increased in transgenic islets. Sorcin may thus provide a target for intervention in type 2 diabetes.

The basic concept of the read-write genome: Mini-review on cell-mediated DNA modification.

The RW genome is a cell-modifiable DNA database encoding RNA and protein sequences. The data files are formatted by repetitive motifs for controlled replication, transmission, expression and repair. Cells have the biochemical natural genetic engineering (NGE) tools needed to make all types of changes to genome DNA. Mobile DNA elements serve as plug-in cassettes that can modify or reformat coding data. Cells regulate and target NGE activities by several well-documented molecular mechanisms. Sequence databases show NGE has operated repeatedly in evolutionary history (e.g., domain swapping in proteins, network rewiring), while experimental studies and cancer cells provide real time examples of NGE action. Experimental tests are feasible to determine whether NGE activities operate in a demonstrably adaptive manner.

Physiology of the read-write genome.

Discoveries in cytogenetics, molecular biology, and genomics have revealed that genome change is an active cell-mediated physiological process. This is distinctly at variance with the pre-DNA assumption that genetic changes arise accidentally and sporadically. The discovery that DNA changes arise as the result of regulated cell biochemistry means that the genome is best modelled as a read-write (RW) data storage system rather than a read-only memory (ROM). The evidence behind this change in thinking and a consideration of some of its implications are the subjects of this article. Specific points include the following: cells protect themselves from accidental genome change with proofreading and DNA damage repair systems; localized point mutations result from the action of specialized trans-lesion mutator DNA polymerases; cells can join broken chromosomes and generate genome rearrangements by non-homologous end-joining (NHEJ) processes in specialized subnuclear repair centres; cells have a broad variety of natural genetic engineering (NGE) functions for transporting, diversifying and reorganizing DNA sequences in ways that generate many classes of genomic novelties; natural genetic engineering functions are regulated and subject to activation by a range of challenging life history events; cells can target the action of natural genetic engineering functions to particular genome locations by a range of well-established molecular interactions, including protein binding with regulatory factors and linkage to transcription; and genome changes in cancer can usefully be considered as consequences of the loss of homeostatic control over natural genetic engineering functions.

Epigenetic control of mobile DNA as an interface between experience and genome change.

Mobile DNA in the genome is subject to RNA-targeted epigenetic control. This control regulates the activity of transposons, retrotransposons and genomic proviruses. Many different life history experiences alter the activities of mobile DNA and the expression of genetic loci regulated by nearby insertions. The same experiences induce alterations in epigenetic formatting and lead to trans-generational modifications of genome expression and stability. These observations lead to the hypothesis that epigenetic formatting directed by non-coding RNA provides a molecular interface between life history events and genome alteration.

Constraint and opportunity in genome innovation.

The development of rigorous molecular taxonomy pioneered by Carl Woese has freed evolution science to explore numerous cellular activities that lead to genome change in evolution. These activities include symbiogenesis, inter- and intracellular horizontal DNA transfer, incorporation of DNA from infectious agents, and natural genetic engineering, especially the activity of mobile elements. This article reviews documented examples of all these processes and proposes experiments to extend our understanding of cell-mediated genome change.