A new beginning with new ends: linearisation of circular chromosomes during bacterial evolution

Bacterial circular chromosomes have sporadically become linearised during prokaryote evolution. Unrelated bacteria, including the spirochete Borrelia burgdorferi and the actinomycete Streptomyces, have linear chromosomes. Linear chromosomes may have been formed through integration of linear plasmids. Linear chromosomes use linear plasmid strategies to resolve the 'end-of-replication problem', but they have generally retained from their circular ancestors a central origin of replication. Streptomyces linear chromosomes are very unstable and at high frequency undergo amplifications and large deletions, often removing the telomeres. At least in Streptomyces, chromosome linearity is reversible: circular chromosomes arise spontaneously as products of genetic instability or can be generated artificially by targeted recombination. Streptomyces circularised chromosomes are very unstable as well, indicating that genetic instability is not confined to the linearised chromosomes. Bacterial linear chromosomes may contain telomere-linked regions of enhanced genomic plasticity, which undergo more frequent genetic exchanges and rearrangements and allow differential evolution of genes, depending on their chromosomal location.     

转座子在植物XY性染色体起源与演化过程中的作用

XY性染色体决定系统是决定植物性别的主要方式,但是对于其起源与演化机制却知之甚少。目前认为,携带控制雌蕊或雄蕊发育基因的一对常染色体由于某种未知原因的突变形成早期的neo-Y或neo-X性染色体,随着演化的进行,早期XY性染色体之间的重组逐渐受到抑制,非重组区域扩展最终形成异型的性染色体。研究发现,重复序列的累积以及DNA甲基化等因素都可能参与了XY性染色体的异染色质化、重组抑制及Y染色体体积增大过程。转座子作为一种基因组中含量最高的重复序列在性染色体演化中扮演了重要的角色,包括性染色体演化的起始激发,以及导致性染色体局部表观遗传修饰使其发生异染色质化扩展和重组抑制。文章综述了转座子在植物性染色体上的累积及其与性染色体异染色质化之间的关系,并简要分析了转座子在性染色体演化过程中的作用。     

Wheel-running activity: a new interpretation

The wheel-running activity of caged mammals has been misinterpreted for many years as a measure of 'general activity'. A review of the literature and recent experimental evidence suggests that this behaviour has a far more specific function for the animal, and that its major and invaluable experimental use lies as both a field and laboratory tool for the studies of particular forms of migration. This new interpretation allows a greater understanding of the motivations underlying this widely-monitored behaviour.

Summary

It is apparent that the nature of the response to an activity-wheel has been greatly misunderstood for many years. The behaviour appears to be far more specific than previously thought, reflecting a type of inherent response which is not evident when activity is recorded by other methods. This report indicates that the wheel is used by a caged animal when the individual is motivated to reach an unattainable resource. This results in an urge to travel, either to remove itself from the immediate area, or to search for specific resources. It is proposed that when the goal is perceptually not present, the activity wheel is a specific monitor of 'exploratory migration', and reflects the urge to collect information about the location of resources. It implies, therefore, that the use of the activity-wheel as a simple measure of 'general activity' should cease; the major future uses of this particular activity recording device should be in the studies of the daily, ontogenetic and seasonal variation in the incidence of exploratory migration, and the influence upon it of other environ- mental factors, as well as a method of investigating goal-orientation, both in the field and the laboratory. This new interpretation provides a more precise explanation of what is being measured in wheel-running experiments, and should result in a more specific use of wheel-activity in experimentation.     

A new look at the evolution of avian sex chromosomes

Birds have a ubiquitous, female heterogametic, ZW sex chromosome system. The current model suggests that the Z chromosome and its degraded partner, the W chromosome, evolved from an ancestral pair of autosomes independently from the mammalian XY male heteromorphic sex chromosomes--which are similar in size, but not gene content (Graves, 1995; Fridolfsson et al., 1998). Furthermore the degradation of the W has been proposed to be progressive, with the basal clade of birds (the ratites) possessing virtually homomorphic sex chromosomes and the more recently derived birds (the carinates) possessing highly heteromorphic sex chromosomes (Ohno, 1967; Solari, 1993). Recent findings have suggested an alternative to independent evolution of bird and mammal chromosomes, in which an XY system took over directly from an ancestral ZW system. Here we examine recent research into avian sex chromosomes and offer alternative suggestions as to their evolution.     

Plant evolution: modern sex chromosomes

The first detailed map has been produced of a plant chromosome carrying sex-determining genes. The new data show that, in papaya, these genes lie in a quite extensive non-recombining region. This region is nevertheless a small part of the papaya genome compared with other male-specific genome regions, such as mammalian Y chromosomes.     

Genetic interpretation of polytene chromosomes banding pattern

This mini-review covers new data regarding the problem of the functional organization of polytene chromosomes: The localization of RNA synthesis in the polytene chromosome puffs, diffuse bands and interbands; The relative stability of banding pattern and its functional value; The informational content of bands.     

The evolution of eutherian chromosomes

The gross organization of the genome of Eutheria (placental mammals) into chromosomes follows a simple architecture that, with some minor changes, is almost completely conserved for more than 100 million years in various species of almost all extant mammalian orders. Recent molecular cytogenetic results--especially those from the assumed oldest clade, the Afrotheria--suggest an ancestral karyotype that would calculate the "default" frequency of gross rearrangements to less than two changes within 10 million years of mammalian evolution. The main changes are the fission, movement and subsequent fusion of large chromosome segments or of chromosome arms. Reciprocal translocations are the exception. Chromosome numbers may have increased or decreased significantly in this fusion/fission process but, in most instances, the main architecture still remains evident. There are, however, some exceptions in mammals with extremely derived karyotypes.     

The evolution of sex chromosomes

Mammalian sex chromosomes appear, behave and function differently than the autosomes, passing on their genes in a unique sex-linked manner. The publishing of Ohno's hypothesis provided a framework for discussion of sex chromosome evolution, allowing it to be developed and challenged numerous times. In this report we discuss the pressures that drove the evolution of sex and the mechanisms by which it occurred. We concentrate on how the sex chromosomes evolved in mammals, discussing the various hypotheses proposed and the evidence supporting them.     

Mating-type locus of Cryptococcus neoformans: a step in the evolution of sex chromosomes

The sexual development and virulence of the fungal pathogen Cryptococcus neoformans is controlled by a bipolar mating system determined by a single locus that exists in two alleles, α and a. The α and a mating-type alleles from two divergent varieties were cloned and sequenced. The C. neoformans mating-type locus is unique, spans >100 kb, and contains more than 20 genes. MAT-encoded products include homologs of regulators of sexual development in other fungi, pheromone and pheromone receptors, divergent components of a MAP kinase cascade, and other proteins with no obvious function in mating. The α and a alleles of the mating-type locus have extensively rearranged during evolution and strain divergence but are stable during genetic crosses and in the population. The C. neoformans mating-type locus is strikingly different from the other known fungal mating-type loci, sharing features with the self-incompatibility systems and sex chromosomes of algae, plants, and animals. Our study establishes a new paradigm for mating-type loci in fungi with implications for the evolution of cell identity and self/nonself recognition.     

Fourfold paralogy regions on human HOX-bearing chromosomes: Role of ancient segmental duplications in the evolution of vertebrate genome

BackgroundSusumu Ohno’s idea that modern vertebrates are degenerate polyploids (concept referred as 2R hypothesis) has been the subject of intense debate for past four decades. It was proposed that intra-genomic synteny regions (paralogons) in human genome are remains of ancient polyploidization events that occurred early in the vertebrate history. The quadruplicated paralogon centered on human HOX clusters is taken as evidence that human HOX-bearing chromosomes were structured by two rounds of whole genome duplication (WGD) events.ResultsEvolutionary history of human HOX-bearing chromosomes (chromosomes 2/7/12/17) was evaluated by the phylogenetic analysis of multigene families with triplicated or quadruplicated distribution on these chromosomes. Topology comparison approach categorized the members of 44 families into four distinct co-duplicated groups. Distinct gene families belonging to a particular co-duplicated group, exhibit similar evolutionary history and hence have duplicated simultaneously, whereas genes of two distinct co-duplicated groups do not share their evolutionary history and have not duplicated in concert with each other.ConclusionThe recovery of co-duplicated groups suggests that “ancient segmental duplications and rearrangements” is the most rational model of evolutionary events that have generated the triplicated and quadruplicated paralogy regions seen on the human HOX-bearing chromosomes.     

Woody Polygonaceae from Brazil: new species and a new interpretation

Three new species, Ruprechtia maracaensis, Ruprechtia nitida , and Triplaris matogrossensis are described. Ruprechtia glauca is a poorly known species from the state of Bahia. Its relationship with R. laxiflora is discussed.     

Trends in the evolution of reptilian chromosomes

Reptiles are a karyologically heterogeneous group, where some orders and suborders exhibit characteristics similar to those of anamniotes and others share similarities with homeotherms. The class also shows different evolutionary trends, for instance in genome and chromosome size and composition. The turtle DNA base composition is similar to that of mammals, whereas that of lizards and snakes is more similar to that of anamniotes. The major karyological differences between turtles and squamates are the size and composition of the genome and the rate at which chromosomes change. Turtles have larger and more variable genome sizes, and a greater amount of middle repetitive DNA that differs even among related species. In lizards and snakes size of the genome are smaller, single-copy DNA is constant within each suborder, and differences in repetitive DNA involve fractions that become increasingly heterogeneous with widening phylogenetic distance. With regard to variation in karyotype morphology, turtles and crocodiles show low variability in chromosome number, morphology, and G-banding pattern. Greater variability is found among squamates, which have a similar degree of karyotypic change-as do some mammals, such as carnivores and bats-and in which there are also differences among congeneric species. An interesting relationship has been highlighted in the entire class Reptilia between rates of change in chromosomes, number of living species, and rate of extinction. However, different situations obtain in turtles and crocodiles on the one hand, and squamates on the other. In the former, the rate of change in chromosomes is lower and the various evolutionary steps do not seem to have entailed marked chromosomal variation, whereas squamates have a higher rate of change in chromosomes clearly related to the number of living species, and chromosomal variation seems to have played an important role in the evolution of several taxa. The different evolutionary trends in chromosomes observed between turtles and crocodiles on the one hand and squamates on the other might depend on their different patterns of G-banding.     

Sex chromosomes: evolution of the weird and wonderful

New findings in the platypus and Drosophila pseudoobscura illustrate, yet again, that the sex chromosomes seem never to stop evolving. Degeneration processes lead to a continual loss of genes and gene activity on the Y chromosome, and complete loss of Y-linked genes is possible if autosomal genes take over control of male fertility - though addition of new material to the sex chromosomes may start the process anew.     

Terminal regions of mammal chromosomes: plasticity and role in evolution

The review considers data on the composition, organization, and functional significance of terminal regions in mammalian chromosomes, including telomeres and subtelomeric regions. Because of specific structure, features of DNA replication, and characteristic localization in somatic and meiotic cells, these regions are hot spots for many events associated with genome functioning in mammals. Instability of these regions is of special interest. Evidence suggesting that instability of chromosomal regions containing telomeric DNA is a factor of chromosome evolution is discussed. The association of size and structure of telomeric regions with replicative aging and cell immortalization is considered. The review deals in detail with classical and alternative mechanisms of telomere size control, the significance of changes in telomeric region length in ontogeny, oncotransformation, and evolution. The issues related to telomere destabilization and the role of this process in chromosome rearrangement formation and chromosome evolution are discussed. The origin of telomere repeats in interstitial chromosome sites, including regions of evolutionary fusions-fissions is given special consideration. The possible role of ribosomal repeats and mechanisms similar to ALT (alternative lengthening of telomeres) in telomere reorganization in some taxa are discussed.