Why do female primates have such long lifespans and so few babies? or Life in the slow lane

A major goal of life history studies is to identify and explain features of the life history of individual species that follow broad rules across many groups of organisms, features that are characteristic of particular phylogenetic lineages, and features that are specific adaptations, to local ecological situations. In recent years we have developed a general theory of life history that interrelates many aspects of ontogeny and reproduction across a wide range of organisms. Contrasted to most other mammals, primates have long average adult lifespans and few babies per year for their adult body size. This new theory suggests that these aspects of life history follow directly from the fact that primates have slow individual growth rates. This slow growth rate is thus the basic phenomenon that needs explanation to understand primate slowness.     

Organism size promotes the evolution of specialized cells in multicellular digital organisms

Specialized cells are the essence of complex multicellular life. Fossils allow us to study the modification of specialized, multicellular features such as jaws, scales, and muscular appendages. But it is still unclear what organismal properties contributed to the transition from undifferentiated organisms, which contain only a single cell type, to multicellular organisms with specialized cells. Using digital organisms I studied this transition. My simulations show that the transition to specialized cells happens faster in organism composed of many cells than in organisms composed of few cells. Large organisms suffer less from temporarily unsuccessful evolutionary experiments with individual cells, allowing them to evolve specialized cells via evolutionary trajectories that are unavailable to smaller organisms. This demonstrates that the evolution of simple multicellular organisms which are composed of many functionally identical cells accelerates the evolution of more complex organisms with specialized cells.     

The morphological and ontogenetic changes in the Protozoa during the transition to a sessile mode of life

The morphological adaptations of protozoans to sessile mode life and evolutionary changes in ontogeny are considered. There are main morphotypes of sessile protists: stalked organisms that attached to substrate by the extended base of body (basal disk), and unstalked organisms that are flatted on substrate. The origin of the morphotypes was independent in different taxa and involved nonhomologous structures. Adaptation to the sessile mode of life in the protists was connected with the progressive increase in the body size and intensity of organelle functions by polymerisation, subsequent division of function and change of functions. Evolution of adhesive organelles is characterised by growing intensity of their functions by allometric growth (usually without polymerisation), and in some cases with the subsequent division of functions and change of functions. The evolution manifests itself primarily in the organelles that provide interaction of cell with environment. The organelles that ensuring functioning of cell change due to correlations with the organelles of the first group. These two groups of organelles are similar to A.N. Sewertsoff's ecto- and endosomatic organs in multicellular organisms. The ontogeny of the sessile protists included three stages: formation of the migratory stage, distribution and choice of substrate and metamorphosis of the migratory stage after adhesion. As a rule there are no recapitulations on the first stage. The majority of structures tomotes or zoospores are inherited from the parent cell. Thus the present of some ancestral characteristics at the earlier stages of protistean ontogeny is display of the Baer's law. The main features of ontogeny evolution in sessile protists are the anaboly of the additional stages of life cycle, the displays of archallaxis or deviation during the migratory stage formation, and anaboly at the stage of buds morphogenesis after adhesion. At the last stage, the study of recapitulations is most perspective with the decision of phylogenetic problems in sessile protists.     

Nostoc: ein prokaryotischer Vielzeller

The multicellular bacterium Nostoc In 2014 the VAAM selected for the first time a ”microbe of the year“ and the winner was the cyanobacterium Nostoc. This multicellular filamentous prokaryote will be described in this article in more detail, focusing on its adaptations to various environmental conditions and sophisticated cell differentiation processes. The photoautotrophic bacterium can live solely on air and light. Under certain conditions it is able to form spore like cells, mobile short filaments, and N₂‐fixing heterocysts. Hence, Nostoc is a popular partner in several symbiotic interactions with plants and heterotrophic organisms. Its autotrophic lifestyle and the presence of differentiated cells, which show true division of labor, give Nostoc a clear selective advantage in many aquatic and terrestrial habitats. Nostoc is a true multicellular organism having special cell wall structures, which connect the cells and allow the communication between the cells of the filament.     

Cryptic surface-associated multicellularity emerges through cell adhesion and its regulation

The repeated evolution of multicellularity led to a wide diversity of organisms, many of which are sessile, including land plants, many fungi, and colonial animals. Sessile organisms adhere to a surface for most of their lives, where they grow and compete for space. Despite the prevalence of surface-associated multicellularity, little is known about its evolutionary origin. Here, we introduce a novel theoretical approach, based on spatial lineage tracking of cells, to study this origin. We show that multicellularity can rapidly evolve from two widespread cellular properties: cell adhesion and the regulatory control of adhesion. By evolving adhesion, cells attach to a surface, where they spontaneously give rise to primitive cell collectives that differ in size, life span, and mode of propagation. Selection in favor of large collectives increases the fraction of adhesive cells until a surface becomes fully occupied. Through kin recognition, collectives then evolve a central-peripheral polarity in cell adhesion that supports a division of labor between cells and profoundly impacts growth. Despite this spatial organization, nascent collectives remain cryptic, lack well-defined boundaries, and would require experimental lineage tracking technologies for their identification. Our results suggest that cryptic multicellularity could readily evolve and originate well before multicellular individuals become morphologically evident.

This modelling study reveals that cell adhesion can lead to the cryptic origination of surface-associated multicellularity, where collectives cannot be distinguished by eye but nonetheless express emergent multicellular adaptations.     

The cell theory. Progress in studies on cell-cell communications

Current data confirm the fundamental statement of the cell theory concerning the cell reproduction in a series of generations (omnis cellula e cellula). Cell communities or ensembles integrated by the signaling systems established in prokaryotes and protists and functioning in multicellular organisms including mammals are considered as the structural and functional unit of a multicellular organism. The cell is an elementary unit of life and basis of organism development and functioning. At the same time, the adult organism is not just a totality of cells. Multinucleated cells in some tissues, syncytial structure, and structural-functional units of organs are adaptations for optimal functioning of the multicellular organism and manifestations of cell-cell communications in development and definitive functioning. The cell theory was supplemented and developed by studies on cell-cell communications; however, these studies do not question the main generalizations of the theory.     

The genetic program of cell death. hypothesis and some applications: Transformation,carcinogenesis, ageing

Cell death is an essential event in the formation and functioning of multicellular organisms. Numerous data indicate that different forms of cell death (programmed, physiological, “violent”, “causeless”) are accompanied by regular enzymatic degradation of nuclear DNA. It has been shown for many cases that degradation of the genetic material occurs in the morphologically intact cells and is not the consequence of activation of hydrolytic enzymes in dead cells. These data suggest that molecular mechanisms of different forms of cell have many common features.A hypothesis is advanced on the existence in the cells of multicellular eukaryotes of the genetic program whose realization causes irreversible degradation of DNA and cell death. This program is supposed to arise at the early stages of evolution of multicellular eukaryotes when the viability of an organism became to be dependent on the normal functioning of its cells. The initial destination of this program was to eliminate the damaged cells that appeared harmful for the whole organism. The appearance of this genetic program became the basis for further evolution of the eukaryotes, for it made possible the arising of higher organisms with the complicated processes of morphogenesis, requiring regular death of a great number of cells at different stages of embriogenesis, and with regular changing of the cellular populations in an adult individual. As a result, the program appeared to be irreversibly fixed in the genome of eukaryotes. By means of the program physiological and programmed cell death are accomplished as well as the death of damaged or abnormally functioning cells in many instances.It may be assumed in particular that one of the functions of the program is to eliminate the constantly appearing cells with oncogenic features. Hence, for the cell to become malignant two events are necessary, viz. oncogenic mutation and changing of cell death program. A special case of modification of the program is transformation which leads to the infinite proliferation of cells in a culture and preservation in the population of constantly arising cells with oncogenic mutations. Thus the advanced hypothesis permits to explain from new positions the two-step nature of different forms of carcinogenesis and to consider from the common view-point the chemical, viral, spontaneous and inheritable carcinogenesis and the role in this process of various oncogenic factors.Ageing is considered as a pleiotropic action of cell death program resulting in gradual reduction of the amount of non-dividing cells, damaged or abnormally functioning due to the action of various internal and external factors. Some other applications of the advanced hypothesis are also examined.     

Intercellular communication and carcinogenesis

Two types of intercellular communication (humoral and cell contact-mediated) are involved in control of cellular function in multicellular organisms, both of them mediated by membrane-embedded proteins. Involvement of aberrant humoral communication in carcinogenesis has been well documented and genes coding for some growth factors and their receptors have been classified as oncogenes. More recently, cell contact-mediated communication has been found to have an important role in carcinogenesis, and some genes coding for proteins involved in this type of communication appear to form a family of tumor-suppressor genes. Both homologous (among normal or (pre-)cancerous cells) as well as heterologous (between normal and (pre)cancerous cells) communications appear to play important roles in cell growth control. Gap junctional intercellular communication (GJIC) is the only means by which multicellular organisms can exchange low molecular weight signals directly from within one cell to the interior of neighboring cells. GJIC is altered by many tumor-promoting agents and in many human and rodent tumors. We have recently shown that liver tumor-promoting agents inhibit GJIC in the rat liver in vivo. Molecular mechanisms which could lead to aberrant GJIC include: (1) mutation of connexin genes; (2) reduced and/or aberrant expression of connexin mRNA; (3) aberrant localization of connexin proteins, i.e., intracytoplasmic rather than in the cytoplasmic membrane; and (4) modulation of connexin functions by other proteins, such as those involved in extracellular matrix and cell adhesion. Whilst mutations of the cx 32 gene appear to be rare in tumors, cx 37 gene mutations have been reported in a mouse lung tumor cell line. Our results suggest that aberrant connexin localization is rather common in cancer cells and that possible molecular mechanisms include aberrant phosphorylation of connexin proteins and lack of cell adhesion molecules. Studies on transfection of connexin genes into tumor cells suggest that certain connexin genes (e.g., cx 26, cx 43 and cx 32) act as tumor-suppressor genes.     

PERSPECTIVE: THE EVOLUTIONARY BIOLOGY OF AGING,SEXUAL REPRODUCTION,AND DNA REPAIR

Three recent books on the evolutionary biology of aging and sexual reproduction are reviewed, with particular attention focused on the provocative suggestion by Bernstein and Bernstein (1991) that senescence and genetic recombination are related epiphenomena stemming from the universal challenge to life posed by DNA damages and the need for damage repair. Embellishments to these theories on aging and sex are presented that consider two relevant topics neglected or underemphasized in the previous treatments. The first concerns discussion of cytoplasmic genomes (such as mtDNA), which are transmitted asexually and therefore do not abide by the recombinational rules of nuclear genomes; the second considers the varying degrees of cellular and molecular autonomy which distinguish unicellular from multicellular organisms, germ cells from somatic cells, and sexual from asexual genomes. Building on the Bernsteins' suggestions, two routes to immortality for cell lineages appear to be available to life: an asexual strategy (exemplified by some bacteria), whereby cell proliferation outpaces the accumulation of DNA damages, thereby circumventing Muller's ratchet; and a sexual strategy (exemplified by germlines in multicellular organisms), whereby recombinational repair of DNA damages in conjunction with cell proliferation and gametic selection counter the accumulation of nuclear DNA damages. If true, then elements of both the recombinational strategy (nuclear DNA) and replacement strategy (cytoplasmic DNA) may operate simultaneously in the germ-cell lineages of higher organisms, producing at least some gametes that are purged of the DNA damages accumulated during the lifetime of the somatic parent. For multicellular organisms, production of functionally autonomous and genetically screened gametic cells is a necessary and sufficient condition for the continuance of life.     

Engineering and control of biological systems: A new way to tackle complex diseases

The ongoing merge between engineering and biology has contributed to the emerging field of synthetic biology. The defining features of this new discipline are abstraction and standardisation of biological parts, decoupling between parts to prevent undesired cross-talking, and the application of quantitative modelling of synthetic genetic circuits in order to guide their design. Most of the efforts in the field of synthetic biology in the last decade have been devoted to the design and development of functional gene circuits in prokaryotes and unicellular eukaryotes. Researchers have used synthetic biology not only to engineer new functions in the cell, but also to build simpler models of endogenous gene regulatory networks to gain knowledge of the "rules" governing their wiring diagram. However, the need for innovative approaches to study and modify complex signalling and regulatory networks in mammalian cells and multicellular organisms has prompted advances of synthetic biology also in these species, thus contributing to develop innovative ways to tackle human diseases. In this work, we will review the latest progress in synthetic biology and the most significant developments achieved so far, both in unicellular and multicellular organisms, with emphasis on human health.     

A proposal for using the ensemble approach to understand genetic regulatory networks

Understanding the genetic regulatory network comprising genes, RNA, proteins and the network connections and dynamical control rules among them, is a major task of contemporary systems biology. I focus here on the use of the ensemble approach to find one or more well-defined ensembles of model networks whose statistical features match those of real cells and organisms. Such ensembles should help explain and predict features of real cells and organisms. More precisely, an ensemble of model networks is defined by constraints on the "wiring diagram" of regulatory interactions, and the "rules" governing the dynamical behavior of regulated components of the network. The ensemble consists of all networks consistent with those constraints. Here I discuss ensembles of random Boolean networks, scale free Boolean networks, "medusa" Boolean networks, continuous variable networks, and others. For each ensemble, M statistical features, such as the size distribution of avalanches in gene activity changes unleashed by transiently altering the activity of a single gene, the distribution in distances between gene activities on different cell types, and others, are measured. This creates an M-dimensional space, where each ensemble corresponds to a cluster of points or distributions. Using current and future experimental techniques, such as gene arrays, these M properties are to be measured for real cells and organisms, again yielding a cluster of points or distributions in the M-dimensional space. The procedure then finds ensembles close to those of real cells and organisms, and hill climbs to attempt to match the observed M features. Thus obtains one or more ensembles that should predict and explain many features of the regulatory networks in cells and organisms.     

Rapid increase in viability due to new beneficial mutations in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

It is usually assumed that new beneficial mutations are extremely rare. Yet, few experiments have been performed in multicellular organisms that measure the effect of new beneficial mutations on viability and other measures of fitness. In most experiments, it is difficult to clearly distinguish whether adaptations have occurred due to selection on new beneficial mutations or on preexisting genetic variation. Using a modification of a Dobzhansky and Spassky (Evolution 1:191–216, 1947) assay to study change in viability over generations, we have observed an increase in viability in lines homozygous for the second and third chromosomes of Drosophila melanogaster in 6–26 generations due to the occurrence of new beneficial mutations in population sizes of 20, 100 and 1,000. The lines with the lowest initial viability responded the fastest to new beneficial mutations. These results show that new beneficial mutations, along with selection, can quickly increase viability and fitness even in small populations. Hence, new advantageous mutations may play an important role in adaptive evolution in higher organisms.     

Bacterial programmed cell death and multicellular behavior in bacteria

Traditionally, programmed cell death (PCD) is associated with eukaryotic multicellular organisms. However, recently, PCD systems have also been observed in bacteria. Here we review recent research on two kinds of genetic programs that promote bacterial cell death. The first is mediated by mazEF, a toxin–antitoxin module found in the chromosomes of many kinds of bacteria, and mainly studied in Escherichia coli. The second program is found in Bacillus subtilis, in which the skf and sdp operons mediate the death of a subpopulation of sporulating bacterial cells. We relate these two bacterial PCD systems to the ways in which bacterial populations resemble multicellular organisms.     

Unlocking the Black Box between Genotype and Phenotype: Cell Condensations as Morphogenetic (modular) Units

Embryonic development and ontogeny occupy whatis often depicted as the black box betweengenes – the genotype – and the features(structures, functions, behaviors) of organisms– the phenotype; the phenotype is not merelya one-to-one readout of the genotype. Thegenes home, context, and locus of operation isthe cell. Initially, in ontogeny, that cell isthe single-celled zygote. As developmentensues, multicellular assemblages of like cells(modules) progressively organized as germlayers, embryonic fields, anlage,condensations, or blastemata, enable genes toplay their roles in development and evolution.As modules, condensations are fundamentaldevelopmental and selectable units ofmorphology (morphogenetic units) that mediateinteractions between genotype and phenotype viaevolutionary developmental mechanisms. In ahierarchy of emergent processes, gene networksand gene cascades (genetic modules) link thegenotype with morphogenetic units such ascondensations, while epigenetic processes suchas embryonic inductions, tissue interactionsand functional integration, link morphogeneticunits to the phenotype. To support theseconclusions I distinguish units of heredityfrom units of transmission and discussepigenetic inheritance by tracing the historyof relationship between embryology andevolution, especially the role(s) assigned tocells or to cellular components in generatingtheories of morphological change in evolution.The concept of cells as modular morphogeneticunits is modeled and illustrated using themammalian dentary bone.     

Phylogenetic fate mapping: theoretical and experimental studies applied to the development of mouse fibroblasts

Mutations are an inevitable consequence of cell division. Similarly to how DNA sequence differences allow inferring evolutionary relationships between organisms, we and others have recently demonstrated how somatic mutations may be exploited for phylogenetically reconstructing lineages of individual cells during development in multicellular organisms. However, a problem with such "phylogenetic fate maps" is that they cannot be verified experimentally; distinguishing actual lineages within clonal populations requires direct observation of cell growth, as was used to construct the fate map of Caenorhabditis elegans, but is not possible in higher organisms. Here we employ computer simulation of mitotic cell division to determine how factors such as the quantity of cells, mutation rate, and the number of examined marker sequences contribute to fidelity of phylogenetic fate maps and to explore statistical methods for assessing accuracy. To experimentally evaluate these factors, as well as for the purpose of investigating the developmental origins of connective tissue, we have produced a lineage map of fibroblasts harvested from various organs of an adult mouse. Statistical analysis demonstrates that the inferred relationships between cells in the phylogenetic fate map reflect biological information regarding the origin of fibroblasts and is suggestive of cell migration during mesenchymal development.     

Multi-cellular logistics of collective cell migration

During development, the formation of biological networks (such as organs and neuronal networks) is controlled by multicellular transportation phenomena based on cell migration. In multi-cellular systems, cellular locomotion is restricted by physical interactions with other cells in a crowded space, similar to passengers pushing others out of their way on a packed train. The motion of individual cells is intrinsically stochastic and may be viewed as a type of random walk. However, this walk takes place in a noisy environment because the cell interacts with its randomly moving neighbors. Despite this randomness and complexity, development is highly orchestrated and precisely regulated, following genetic (and even epigenetic) blueprints. Although individual cell migration has long been studied, the manner in which stochasticity affects multi-cellular transportation within the precisely controlled process of development remains largely unknown. To explore the general principles underlying multicellular migration, we focus on the migration of neural crest cells, which migrate collectively and form streams. We introduce a mechanical model of multi-cellular migration. Simulations based on the model show that the migration mode depends on the relative strengths of the noise from migratory and non-migratory cells. Strong noise from migratory cells and weak noise from surrounding cells causes "collective migration," whereas strong noise from non-migratory cells causes "dispersive migration." Moreover, our theoretical analyses reveal that migratory cells attract each other over long distances, even without direct mechanical contacts. This effective interaction depends on the stochasticity of the migratory and non-migratory cells. On the basis of these findings, we propose that stochastic behavior at the single-cell level works effectively and precisely to achieve collective migration in multi-cellular systems.     

Mitochondrial DNA,chloroplast DNA and the origins of development in eukaryotic organisms

Background  

Several proposals have been made to explain the rise of multicellular life forms. An internal environment can be created and controlled, germ cells can be protected in novel structures, and increased organismal size allows a "division of labor" among cell types. These proposals describe advantages of multicellular versus unicellular organisms at levels of organization at or above the individual cell. I focus on a subsequent phase of evolution, when multicellular organisms initiated the process of development that later became the more complex embryonic development found in animals and plants. The advantage here is realized at the level of the mitochondrion and chloroplast.     

The sculpturing role of fibroblast-like cells in morphogenesis

Cells of multicellular organisms are semi-fluid creatures. Even when they form specific cell-cell adhesions, they cannot create a defined shape or a tissue-specific architecture. Cartilaginous organs, such as ears and noses, exemplify the fact that form is imprinted in the extracellular matrix (ECM), which leads to the conclusion that cells must have the ability to shape the ECM in which they reside. This seems to be true for most tissues. The role of the ECM as an integrator of cells into functional assemblies with defined architecture is unique to multicellular organisms. The evolution of multicellularity became possible as a consequence of cells acquiring two new properties: first, cell surface macromolecular complexes that function in cell-cell binding; and, second, an ECM that integrates cells into three-dimensional structures. These two new properties allowed the evolution of the two basic types of cells-epithelial and mesenchymal. The appearance of the latter, a fibroblast-like cell with abundant filopodia, enabled the sculpturing of the ECM and the formation of complex tissue-specific architectures.     

Physiological and molecular biological mechanisms underlying diapause in aquatic invertebrates

The review considers the published data, as well as its own, which demonstrate the abundance and evolutionary conservation of the mechanism of diapause in invertebrates. The ecological reasons for the emergence of diapause in life cycles of hydrobionts are analyzed. The specific physiological features of invertebrate diapausing organisms and the hormonal control of diapause are briefed. The molecular genetic mechanism of diapause is demonstrated by the example of a model species, Caenorhabditis elegans. Recent fundamental discoveries in molecular genetics related to the joint effect of genes and environmental factors on the basic metabolism, choice between the development-diapause alternative, and many other seasonal adaptations in multicellular organisms are discussed. The near discovery of the functional role of daf genes in hydrobionts is postulated. These studies will lead to a deeper understanding of the fine mechanism that underlies photoperiodism and the wider application of diapause phenomenon in theory and practice.