Ontogeny and phylogeny in papionin primates

This study investigates the developmental bases of size and shape variation in papionin primates (Macaca, Cercocebus, Mandrillus, Lophocebus, and Papio). The analysis tests hypotheses predicting that heterochronic changes in ontogeny, particularly in the degree of overall size growth, can account for cranial diversity and "allometric scaling" in this clade. Large developmental samples of extant papionin crania are examined to test heterochronic hypotheses using bivariate allometric methods. Analyses indicate that the crania of larger papionins (Mandrillus and Papio) are generally peramorphic, surpassing size and shape ranges of smaller, and probably less-derived, macaques and mangabeys. At least two heterochronic processes, including acceleration and hypermorphosis, can account for this pattern. Ontogenetic changes include decoupling of growth and development among cranial regions, along with simple shifts in size. Allometric scaling has complex developmental bases. Size change itself is not sufficient to explain all developmental differences among papionins, but these changes are extremely important in comparisons within cranial regions such as the face. Results imply that Papio exhibits strongly derived patterns of brain growth that impact postnatal patterns of size and shape transformation. Consideration of these results in the context of recent socioecological analyses suggests that derived patterns of cranial growth in Papio may be a response to selection during the early periods of ontogeny, resulting in a distinctive life history pattern.     

几丁质合酶在人类致病真菌中的研究进展

抑制真菌细胞壁的合成常作为防治真菌感染的安全有效手段。几丁质是真菌细胞壁及隔膜的重要结构成分，几丁质合酶是催化几丁质合成的关键酶。真菌细胞中几丁质合酶家族的不同成员在调控几丁质的合成中存在着差异，因此产生不同的生物学效应。本文通过综述几丁质合酶在人体三大条件致病真菌白色念珠菌、烟曲霉、新生隐球菌中的研究进展，分析了几丁质合酶对真菌致病性影响的机制，总结了几丁质合酶调控真菌细胞增殖、形态转换、病原菌与宿主的相互作用和细胞壁损伤诱导的补偿效应，展望了抗真菌感染的新策略及关于真菌几丁质合酶的未来研究方向。     

Ontogeny and phylogeny: a quantitative theory of heterochrony

Developmental variability in organisms underlies the relationship between ontogeny and phylogeny. The concept entropy permits a quantitative characterization of this variability and provides a basis for interpreting the phylogeny of heterochrony in evolution.     

Ontogeny, phylogeny and the origin of biological information.

Accepting the evidence that evolution is largely finished and that sexual reproduction is incapable of supporting macroevolution, indicates that macroevolutionary changes were produced presexually through the cytological events associated with the first meiotic division. This reproductive mode is ideally suited to the production of new structural rearrangements of preexisting genetic information in instantaneous homozygous form. These new arrangements (position effects) produce new and discrete species. Thus, speciation results not from new genetic information, but rather from information already present (preformed). The several parallels that exist between epigenesis and preformation in both ontogeny (development) and phylogeny (evolution) are discussed. I propose that both of these phenomena have proceeded through the selective activation (derepression) of an enormous potential supply of information already present at the onset of each of these biological phenomena. Acceptance of these possibilities can serve to liberate us in our quest for the ultimate truth concerning these two closely related phenomena.     

Ontogeny discombobulates phylogeny: paedomorphosis and higher-level salamander relationships

Evolutionary developmental biology ("evo-devo") has revolutionized evolutionary biology but has had relatively little impact on systematics. We show that similar large-scale developmental changes in distantly related lineages can dramatically mislead phylogenetic analyses based on morphological data. Salamanders are important model systems in many fields of biology and are of special interest in that many species are paedomorphic and thus never complete metamorphosis. A recent study of higher-level salamander phylogeny placed most paedomorphic families in a single clade based on morphological data. Here, we use new molecular and morphological data to show that this result most likely was caused by the misleading effects of paedomorphosis. We also provide a well-supported estimate of higher-level salamander relationships based on combined molecular and morphological data. Many authors have suggested that paedomorphosis may be problematic in studies of salamander phylogeny, but this hypothesis has never been tested with a rigorous phylogenetic analysis. We find that the misleading effects of paedomorphosis on phylogenetic analysis go beyond the sharing of homoplastic larval traits by paedomorphic adults, and the problem therefore is not solved by simply excluding suspected paedomorphic characters. Instead, two additional factors are critically important in causing paedomorphic species to be phylogenetically "misplaced": (1) the absence of clade-specific synapomorphies that develop during metamorphosis in nonpaedomorphic taxa and allow their "correct" placement and (2) parallel adaptive changes associated with the aquatic habitat of the larval stage. Our results suggest that the effects of paedomorphosis on phylogenetic analyses may be complex, difficult to detect, and can lead to results that are both wrong and statistically well supported by parsimony and Bayesian analyses.     

Ontogeny and phylogeny in temnospondyls: a new method of analysis

A new method has been devised to compare the ontogeny and phylogeny of some of the better documented tetrapods from the Stephanian to the Trias. This approach is based on global parsimony analysis of several temnospondyl amphibians, in which some ontogenetic sequences have been highlighted. Forty-one homologous morphoanatomical character states have been separated into larval, juvenile and adult stages of each of six tetrapod species. The taxonomic congruence (TC) approach involves comparing trees based on larval, juvenile and adult character states. These so-called 'ontotrees' are not congruent, either in their topologies or in the distribution of the character states. The total evidence (TE) approach involves a combined analysis of all the character states observed in the various growth stages of the taxa, and is secondarily used in order to test this taxonomic incongruence. In this case, the TE result corroborates the TC analysis: the TE tree is robust and reveals a few homoplasies which cause the taxonomic incongruence. This is interpreted as either the result of heterochronic events in temnospondyl evolution, or as the product of inaccurate identification of larval and metamorphic fossil forms.     

Ontogeny and phylogeny in the evolutionary biochemistry space

The process of evolution is considered as the change of nucleotide sequence in an (N+1)-dimensional or 3-dimensional space. Restricting conditions may be represented by the shape of a tunnel, through which points or a rope representing nucleic acids move along with time, and may be similar for ontogenetic and phylogenetic development.     

Ontogeny and phylogeny in the evolutionary biochemistry space

The process of evolution is considered as the change of nucleotide sequence in an (N+1)-dimensional or 3-dimensional space. Restricting conditions may be represented by the shape of a tunnel, through which points or a rope representing nucleic acids move along with time, and may be similar for ontogenetic and phylogenetic development.     

Ontogeny and phylogeny of Brownleea (Orchidoideae: Orchidaceae)

The phylogeny of the African orchidoid genus Brownleea was investigated, using morphological characters. It has been suggested that the genus may be of hybrid origin, a hypothesis supported by the presence of two very different types of stigma ontogenies. Morphological investigations of all the species revealed that two species have stigmas derived from all three carpel apices, the 'normal' situation in the Orchidaceae. The remaining five species have stigmas derived from only the median carpel, a very unusual situation found in the Coryciinae. A phylogenetic analysis of all available morphological data for all species supports the monophyly of the genus. based on several distinct synapomorphies. The variation in stigma ontogeny may be due either to parallelism, or to an earlier hybridization event. The analysis supported the recognition of several distinct groupings within Brownleea . Two of these groupings are supported irrespective of which putative parent is used as sister-group to the genus, while a third grouping is dependent on the use of the as sister-group.     

Aspergillus nidulans class V and VI chitin synthases CsmA and CsmB, each with a myosin motor-like domain, perform compensatory functions that are essential for hyphal tip growth

The polarized synthesis of cell wall components such as chitin is essential for the hyphal tip growth of filamentous fungi. The actin cytoskeleton is known to play important roles in the determination of hyphal polarity in Aspergillus nidulans. Previously, we suggested that CsmA, a chitin synthase with a myosin motor-like domain (MMD), was involved in polarized chitin synthesis in a manner dependent on the interaction between the MMD and the actin cytoskeleton. The genome database indicates that A. nidulans possesses another gene encoding another chitin synthase with an MMD. In this study, we characterized this gene, which we designated csmB. The csmB null mutants examined were viable, although they exhibited defective phenotypes, including the formation of balloons and intrahyphal hyphae and the lysis of subapical regions, which were similar to those obtained with csmA null mutants. Moreover, csmA csmB double null mutants were not viable. Mutants in which csmB was deleted and the expression of csmA was under the control of the alcA promoter were viable but severely impaired in terms of hyphal growth under alcA-repressing conditions. We revealed that CsmB with three copies of a FLAG epitope tag localized at the hyphal tips and forming septa, and that the MMD of CsmB was able to bind to actin filaments in vitro. These results suggest that CsmA and CsmB perform compensatory functions that are essential for hyphal tip growth.     

葡萄座腔菌科研究进展——鉴定,系统发育学和分子生态学

葡萄座腔菌科（Botryosphaeriaceae）真菌是农业和林业上重要的病原菌、内生真菌或潜在的致病菌,主要引起树木溃疡病。这类真菌种类繁多,寄主范围广,广泛分布于全球,在生态系统中占有重要的地位。本文综述了近年来国内外在葡萄座腔菌科的分子生态学研究方面取得的新进展。简要介绍了葡萄座腔菌科真菌物种鉴定及其研究方法方面的发展,并列出了2006年以来发现的6个新属和38个新种;概述了该科各个种、属之间的系统发育关系以及科内区分的18个群。在真菌种群遗传结构及其与寄主关系方面,已有研究表明葡萄座腔菌科真菌大体可分为寄主专化型和广谱寄生型两种类型,并已经揭示了无性型为Diplodia,Lasiodiplodia和Dothiorella等部分种群的遗传结构及它们与寄主之间的联系。在种内遗传多样性和基因流动研究方面,展示了利用ISSR、SSR等分子标记方法取得的一些重要结果,有些种群（如Lasiodiplodia theobromae）没有寄主专化性,它们在不同寄主间表现出很强的基因流动,但在不同区域内的基因交流却很有限。文章最后讨论了该科分子生态学研究有待进一步解决的问题。     

Image analysis of hyphal morphogenesis in Saprolegniaceae (Oomycetes)

Because of their wide range of apical morphology, several members of saprolegniaceous fungi (Oomycetes) were chosen to examine concordance with the vesicle supply center (VSC) model of hyphal morphogenesis. Two computer routines were devised to measure diameter changes over long stretches of hyphae and to test compatibility with the theoretical hyphoid shape, y = xcot(xV/N). In all four genera examined, the apex followed closely the contour described by the hyphoid equation; divergences became evident in the subapex. The hyphae of Saprolegnia parasitica showed maximum concordance with the VSC model, i.e., their profile matched a hyphoid curve from the apex to the entire length of the mature hyphal tube. In Aphanomyces and Leptolegnia, growth in the subapical region subsided becoming less than that specified by the hyphoid equation. In Achlya bisexualis, the reverse was true, the subapical region expanded beyond that specified by the hyphoid equation. The two divergent subapical tendencies gave the hyphal tips a cylindroid or conoid appearance, respectively. Since the hyphal apex of all four species conformed to the curvature dictated by the hyphoid equation, we concluded that a basic VSC mechanism operates in all of these oomycetous fungi. Accordingly, we suggest that the shape of an oomycetous hypha is generated by a VSC-driven gradient of wall formation, which is subject to additional modification in the subapex to produce a range of hyphal tip morphologies. The mathematical basis for generating a conoid hyphal tip by elongating the VSC is described in Appendix A.     

Regulation of hyphal morphogenesis by Ras and Rho small GTPases

The fungal kingdom is extremely diverse – comprised of over 1.5 million species including yeasts, molds and mushrooms. Essentially, all fungi have cell walls that contain chitin and the cells of most fungi grow as tube-like filaments called hyphae. These filamentous fungi, such as the mold Neurospora crassa, develop branched radial networks of hyphae referred to as mycelium. In contrast, non-filamentous fungi do not form radial mycelia, but grow as single cells, which reproduce by either budding or fission such as Saccharomyces cerevisiae or Schizosaccharomyces pombe, respectively. Finally, there are fungi that are capable of switching between single cell, yeast form growth and filamentous growth such as Candida albicans. The switch from yeast to filamentous growth in these so-called dimorphic fungi is a virulence trait in many human and plant pathogens. Highly conserved master regulators of all three fungal growth modes – filamentous, non-filamentous and dimorphic – are the Ras and Rho small GTPases, which spatially and temporally control cell polarity establishment and maintenance. This review summarizes the key roles of the Ras and Rho GTPases during hyphal morphogenesis in a range of fungi.     

Evolution and phylogenetic relationships of chitin synthases from yeasts and fungi

Chitin, the structural component that provides rigidity to the cell wall of fungi is the product of chitin synthases (Chs). These enzymes are not restricted to fungi, but are amply distributed in four of the five eukaryotic 'crown kingdoms'. Dendrograms obtained by multiple alignment of Chs revealed that fungal enzymes can be classified into two divisions that branch into at least five classes, independent of fungal divergence. In contrast, oomycetes and animals each possess a single family of Chs. These results suggest that Chs originated as a branch of beta-glycosyl-transferases, once the kingdom Plantae split from the evolutionary line of eukaryotes. The existence of a single class of Chs in animals and Stramenopiles, against the multiple families in fungi, reveals that Chs diversification occurred after fungi departed from these kingdoms, but before separation of fungal groups. Accordingly, each fungal taxon contains members with enzymes belonging to different divisions and classes. Multiple alignment revealed the conservation of specific motifs characteristic of class, division and kingdom, but the strict conservation of only three motifs QXXEY, EDRXL and QXRRW, and seven isolated amino acids in the core region of all Chs. Determination of different structural features in this region of Chs brought to light a noticeable conservation of secondary structure in the proteins.     

Spitzenkorper localization and intracellular traffic of green fluorescent protein-labeled CHS-3 and CHS-6 chitin synthases in living hyphae of Neurospora crassa

The subcellular location and traffic of two selected chitin synthases (CHS) from Neurospora crassa, CHS-3 and CHS-6, labeled with green fluorescent protein (GFP), were studied by high-resolution confocal laser scanning microscopy. While we found some differences in the overall distribution patterns and appearances of CHS-3-GFP and CHS-6-GFP, most features were similar and were observed consistently. At the hyphal apex, fluorescence congregated into a conspicuous single body corresponding to the location of the Spitzenkörper (Spk). In distal regions (beyond 40 μm from the apex), CHS-GFP revealed a network of large endomembranous compartments that was predominantly comprised of irregular tubular shapes, while some compartments were distinctly spherical. In the distal subapex (20 to 40 μm from the apex), fluorescence was observed in globular bodies that appeared to disintegrate into vesicles as they advanced forward until reaching the proximal subapex (5 to 20 μm from the apex). CHS-GFP was also conspicuously found delineating developing septa. Analysis of fluorescence recovery after photobleaching suggested that the fluorescence of the Spk originated from the advancing population of microvesicles (chitosomes) in the subapex. The inability of brefeldin A to interfere with the traffic of CHS-containing microvesicles and the lack of colocalization of CHS-GFP with the endoplasmic reticulum (ER)-Golgi body fluorescent dyes lend support to the idea that CHS proteins are delivered to the cell surface via an alternative route distinct from the classical ER-Golgi body secretory pathway.Fungal hyphae elongate and branch by a complex process based on polarized secretion. Many studies have investigated the cellular and molecular components involved in shaping fungal cells, but no detailed understanding of the mechanisms that govern and regulate polarized fungal growth has been achieved (4, 25). In the yeast Saccharomyces cerevisiae, many of the main components of the secretory pathway, including some of the enzymes involved in cell wall formation, have been extensively characterized (32). Filamentous fungi encode homologues of some key components known from the yeast secretory pathway, but despite their apparent orthology, relatively little is known about how this pathway is organized to accomplish the highly polarized growth typical of hyphae. There are some differences in cell wall synthesis between filamentous fungi and S. cerevisiae. In hyphae of septate fungi, vesicles and other components accumulate at the apex, as part of the Spitzenkörper (Spk) (14, 22-24, 28). The composition and mode of action of this pleomorphic and dynamic structure have intrigued fungal biologists for many decades.Fungal cells have at least two types of well-defined secretory vesicles (5). It has been suggested that macrovesicles, or conventional secretory vesicles, carry the components of the amorphous phase of the cell wall, in addition to the load of extracellular enzymes (5, 27). There is a large body of evidence characterizing the chitin synthase (CHS)-carrying microvesicles as chitosomes (3, 8, 13, 30). CHS are β-glycosyltransferases that catalyze the polymerization of N-acetylglucosamine from UDP N-acetylglucosamine into chitin (47), a major structural polymer of the fungal cell wall (2). Chitin synthesis occurs in highly localized fashion both at the hyphal apices (7) and at nascent septa (29). Chitosomes are the smallest vesicles with the ability to form chitin microfibrils in vitro and have been suggested to carry and transport CHS to the cell surface at the apex of hyphae for cell wall synthesis (13, 37, 48, 55, 56). In recent years, studies on fungal CHS have concentrated mainly on gene identification. Given this wealth of information, we chose CHS as candidate markers to investigate vesicle traffic in fungal hyphae.Fungi have multiple chs genes grouped into two divisions, with seven classes, primarily on the basis of similarities in the primary sequence of the predicted proteins (12, 16, 37, 50). Division I includes classes I, II, and III, which share a catalytic domain surrounded by a hydrophilic N-terminal region and a hydrophobic C-terminal region (12). Division II includes classes IV, V, and VII, all with a catalytic domain preceded by a cytochrome b₅-like domain. In addition, classes V and VII contain an N-terminal myosin motor-like domain, suggesting a direct interaction with the actin cytoskeleton (15, 20, 58). Class VI has not been assigned to either division and includes recently identified CHS of unknown function (16). Earlier studies suggest that the various CHS have specific roles in chitin cell wall synthesis that are time or space dependent (60). In contrast to most filamentous fungi, S. cerevisiae (46) and Candida albicans (40) have only three or four CHS isozymes, respectively. S. cerevisiae Chs1p, C. albicans Chs2p, and C. albicans Chs8p belong to class I; S. cerevisiae Chs2p and C. albicans Chs1p belong to class II; and S. cerevisiae Chs3p and C. albicans Chs3p belong to class IV (46). While potential roles in hyphal growth have been suggested for some of the seven CHS classes described in filamentous fungi (9, 64, 65), we lack specific information on the cellular localization and trafficking to their sites of action in regions of active cell wall growth for most of these proteins.The goal of this study was to elucidate the traffic of CHS-containing vesicles en route from their site of genesis to their site of exocytosis in living hyphae of Neurospora crassa. The availability of an almost-complete genome sequence for this fungus allowed the identification of seven open reading frames with high homology to previously described chs genes (10). We chose to trace the intracellular location and secretory paths of CHS-3 and CHS-6. Neurospora CHS-3 belongs to the previously reported class I CHS with known homologues in all fungi tested, including S. cerevisiae Chs1p. In contrast, CHS-6 is a newly identified CHS assigned to class VI, homologous to Aspergillus fumigatus ChsD (39) and Coccidioides posadasii CHS-6 (34) but with no apparent homologues in S. cerevisiae or C. albicans. To trace both proteins, we fused green fluorescent protein (GFP) to the carboxyl terminus of the CHS coding regions and analyzed the fate of the resulting CHS-3-GFP and CHS-6-GFP fusion proteins by high-resolution confocal laser scanning microscopy (CLSM) in living hyphae of N. crassa.     

Involvement of chitin in exoskeleton morphogenesis in Drosophila melanogaster

Exoskeletons stabilize cell, tissue, and body morphology in many living organisms including fungi, plants, and arthropods. In insects, the exoskeleton, the cuticle, is produced by epidermal cells as a protein extracellular matrix containing lipids and the polysaccharide chitin, and its formation requires coordinated synthesis, distribution, and modification of these components. Eventually, the stepwise secretion and sorting of the cuticle material results in a layered structure comprising the envelope, the proteinaceous epicuticle, and the chitinous procuticle. To study the role of chitin during cuticle development, we analyzed the consequences of chitin absence in the embryo of Drosophila melanogaster caused by mutations in the Chitin Synthase-1 (CS-1) gene, called krotzkopf verkehrt (kkv). Our histological data confirm that chitin is essential for procuticle integrity and further demonstrate that an intact procuticle is important to assemble and to stabilize the chitin-less epicuticle. Moreover, the phenotype of CS-1/kkv mutant embryos indicates that chitin is required to attach the cuticle to the epidermal cells, thereby maintaining epidermal morphology. Finally, sclerotization and pigmentation, which are the last steps in cuticle differentiation, are impaired in tissues lacking CS-1/kkv function, suggesting that proper cuticle structure is crucial for the activity of the underlying enzymes.     

Ontogeny and phylogeny: molecular signatures of selection, constraint, and temporal pleiotropy in the development ofDrosophila

Background  

Karl Ernst Von Baer noted that species tend to show greater morphological divergence in later stages of development when compared to earlier stages. Darwin originally interpreted these observations via a selectionist framework, suggesting that divergence should be greatest during ontogenic stages in which organisms experienced varying 'conditions of existence' and opportunity for differential selection. Modern hypotheses have focused on the notion that genes and structures involved in early development will be under stronger purifying selection due to the deleterious pleiotropic effects of mutations propagating over the course of ontogeny, also known as the developmental constraint hypothesis.     

Ontogeny and phylogeny of the pelvis in Gorilla, Pongo, Pan, Australopithecus and Homo

To examine the evolutionary differences between hominoid locomotor systems, a number of observations concerning the growth of the pelvis among the great apes as compared to modern and fossil hominids are reported. We are interested in the size and shape of the coxal bones at different developmental stages across species that may elucidate the relationship between ontogeny and phylogeny (i.e., heterochrony) in the hominoid pelvis. Our hypotheses are: (1) do rates of absolute growth differ?, (2) do rates of relative growth differ?, and (3) does heterochrony explain these differences? Bivariate and multivariate analyses of pelvic dimensions demonstrate both the diversity of species-specific ontogenetic patterns among hominoids, and an unequivocal separation of hominids and the great apes. Heterochrony alone fails to account for the ontogenetic differences between hominids and the great apes. Compared to recent Homo,Australopithecus can be described as 'hyper-human' from the relative size of the ischium, and short but broad ilium. Australopithecus afarensis differs from Australopithecus africanus by its relatively long pubis. In multivariate analyses of ilium shape, the most complete coxal bone attributed to Homo erectus, KNM-ER 3228, falls within the range of juvenile and adult Australopithecus, whereas Broken Hill falls within the range of modern Homo, suggesting that the modern human ilium shape arose rather recently. Among the great apes, patterns of pelvic ontogeny do not exclusively separate the African apes from Pongo.