Phosphatized rare star-like mouth disc of Punctatus and its functional morphology from the earliest Cambrian of the South Shaanxi China

The Meishucun stage is the prelude in deciphering the Cambrian Explosion. In this prominent stage, rapid radioactive evolution and body-plan innovation have taken place and different associations of organism have been shaped. In this paper we report several 3D-preserved rare star-like fossils with finely preserved soft tissues which were recovered from the Kuanchuanpu Member of the Dengying Formation in South Shaanxi, China in 2003. By studying on functional morphology and analogy with mouthpart of Punctatus, there are evidences that this star-like organism approaches the coelenterates in systematic classification and the centre of star-like organism is its mouth. The appearance of coelenterates marks the real beginning of metazoan evolution. Therefore, it has the prominent position in the origin and evolutionary history of organisms. Perhaps the star-like organism represents the early types of coelenterate with original tentacles. These new materials provide new evidence for the origin, evolution and the functional evolution of the metazoan during the early stage of the Cambrian Explosion. __________ Translated from Acta Micropalaeontologica Sinica, 2006, 23(1): 62–69 [译自: 微体古生物学报]     

陕南早寒武世早期Quadrapyrgites再研究

处于"寒武纪生命大爆发"序幕阶段的梅树村期,生物类群大规模辐射,身体构型快速革新,与前寒武纪生物群面貌明显不同.最近在陕南宁强宽川铺地区梅树村期地层中发现了大量五辐射Punctatus及部分四辐射四方塔形壳属Quadrapyrgites,其中包括1个新种Quadrnpyrgites undulatuscostalis sp.nov..在此基础上对Quadrapyrgites进行了属征补充.双胚层腔肠动物的出现标志着地球生命史的真后生动物演化开端,在生物起源演化历程上占据着关键的位置.本文为研究真后生动物起源演化、生物辐射、体型构建提供了重要实证.     

陕南早寒武世早期磷酸盐化Punctatus奇异星状口盘的发现及其形态功能分析

早寒武世最早期梅树村期处于“寒武纪大爆发”序幕阶段。在这一时期,生物类群发生了大规模辐射演化及其身体构型的快速革新,形成与前寒武纪生物群明显不同的生物组合面貌。最近在陕南宽川铺地区早寒武世早期灯影组宽川铺段地层中发现了数十枚呈三维立体精美保存的磷酸盐化奇异星状生物化石标本,通过形态功能分析及与其共生的Punctatus的口盘类比表明,该奇异星状生物很可能属于腔肠动物Punctatus的口盘,星状体的中心为该生物的口部。而腔肠动物的出现标志着真后生动物的开始,在生物起源演化历程上占据着极其关键的位置。本文报道的奇异星状生物可能代表了初具原始触手的腔肠动物早期演化类型,为研究真后生动物起源演化、功能进化提供了新的实证材料。     

陕南早寒武世具口部的磷酸盐化Punctatus及其胚胎化石

报道陕西南部灯影组宽川铺段地层中发现的Punctatus锥体标本、保留精美软组织特征的口部标本和可能的胚胎标本。对Punctatus软组织及整体形态功能研究表明,Punctatus在分类上可能更接近于腔肠动物的水螅型,代表初具原始触手的腔肠动物早期演化类型。在上万枚与Punctatus共生的球状化石中,发现若干枚可能的原肠期胚胎及胚胎发育晚期标本,在此基础上提出PunctatusemeiensisHe,1980花冠状口部可能经历的胚胎发育序列。     

关山生物群中始海百合化石的再研究*

关山生物群是继澄江生物群之后云南寒武纪早期地层中发现的又一个特异埋藏的化石宝库。现已报道10多个门类的化石动物,对研究寒武纪生命大爆发、后生动物起源及演化、寒武纪早期生态系统的复原等重大学术问题具有特殊的意义。始海百合属于棘皮动物门海蕾亚门,于寒武纪早期出现,志留纪灭绝。笔者将荧光显微镜等先进成像方式与传统的研究手段相结合,对新采集到的关山生物群始海百合化石标本进行深入细致的系统古生物学研究,对其精细形态学构造和生活习性获得更深入的了解。这对于认识寒武纪早期的生物多样性和棘皮动物的演化都具有重要的意义。     

寒武纪早期岩家河生物群:研究进展和展望*

埃迪卡拉纪-寒武纪转换时期动物的起源、演化和"寒武纪大爆发"一直是国际古生物学界研究的热点问题,其中寒武纪早期小壳化石群与埃迪卡拉纪化石群和寒武纪早期澄江化石库之间的内在关系是古生物学界研究的难题,其主要原因是寒武纪早期与小壳化石群伴生的宏体动、植物化石的缺乏。发现于峡东地区的寒武纪早期岩家河生物群填补了这一缺失环节,该生物群包含宏体动物、宏观藻类、小壳化石、球形化石(可能的胚胎化石)、微古植物和蓝菌类等化石,部分宏体化石显示了从埃迪卡拉纪向寒武纪过渡色彩。化石保存方式有碳质膜、黄铁矿化、磷酸盐化、硅化。因此对岩家河生物群生物多样性和埋藏学进行综合研究,将可提供纽芬兰世(梅树村期)碳酸盐台地—碳酸盐台地内部的局部凹陷盆地相的一个较完整的生物景观图,对探索"寒武纪大爆发主幕"前夕生物的辐射、演化模式及保存机制具有重要的科学意义。     

Current advances in the phylogenetic reconstruction of metazoan evolution. A new paradigm for the Cambrian explosion?

The study of metazoan evolution has fascinated biologists for centuries, and it will certainly keep doing so. Recent interest on the origin of metazoan body plans, early metazoan evolution, genetic mechanisms generating disparity and diversity, molecular clock information, paleontology, and biogeochemistry is contributing to a better understanding of the current phyletic diversity. Unfortunately, the pattern of the metazoan tree of life still shows some important gaps in knowledge. It is the aim of this article to review some of the most important issues related to the inference of the metazoan tree, and point towards possible ways of solving certain obscure aspects in the history of animal evolution. A new hypothesis of the metazoan diversification during the Cambrian explosion is proposed by synthesizing ideas from phylogenetics, molecular evolution, paleontology, and developmental biology.     

Advanced Cambrian hydroid fossils (Cnidaria: Hydrozoa) extend the medusozoan evolutionary history

Primitive cnidarians are crucial for elucidating the early evolution of metazoan body plans and life histories in the late Neoproterozoic and Palaeozoic. The highest complexity of both evolutionary aspects within cnidarians is found in extant hydrozoans. Many colonial hydrozoans coated with chitinous exoskeletons have the potential to form fossils; however, only a few fossils possibly representing hydroids have been reported, which still require scrutiny. Here, we present an exceptionally well-preserved hydroid found in the Upper Cambrian Fengshan Formation in northern China. It was originally interpreted as a problematic graptolite with an uncertain systematic position. Based on three characteristic morphological traits shared with extant hydroids (with paired hydrothecae, regular hydrocaulus internodes and special intrathecal origin pattern of hydrocladium), we propose this fossil hydroid as a new genus, Palaeodiphasia gen. nov., affiliated with the advanced monophyletic hydrozoan clade Macrocolonia typically showing loss of the medusa stage. More Macrocolonia fossils reviewed here indicate that this life strategy of medusa loss has been achieved already as early as the Middle Devonian. The early stratigraphical appearance of such advanced hydroid contrasts with previous molecular hypotheses regarding the timing of medusozoan evolution, and may be indicative for understanding the Ediacaran cnidarian radiation.     

Exceptionally preserved jellyfishes from the Middle Cambrian

Cnidarians represent an early diverging animal group and thus insight into their origin and diversification is key to understanding metazoan evolution. Further, cnidarian jellyfish comprise an important component of modern marine planktonic ecosystems. Here we report on exceptionally preserved cnidarian jellyfish fossils from the Middle Cambrian (approximately 505 million years old) Marjum Formation of Utah. These are the first described Cambrian jellyfish fossils to display exquisite preservation of soft part anatomy including detailed features of structures interpreted as trailing tentacles and subumbrellar and exumbrellar surfaces. If the interpretation of these preserved characters is correct, their presence is diagnostic of modern jellyfish taxa. These new discoveries may provide insight into the scope of cnidarian diversity shortly after the Cambrian radiation, and would reinforce the notion that important taxonomic components of the modern planktonic realm were in place by the Cambrian period.     

脊椎动物的起源与演化研究进展

脊椎动物的起源与演化历来是进化生命科学的核心命题。近年脊椎动物的起源与演化有重大突破。云南澄江寒武纪化石群中的后口类“皇冠西大动物” ,半索动物“云南虫”和“海口虫” ,尾索动物“始祖长江海鞘” ,头索动物“海口华夏鱼”和“中间型中新鱼” ,脊椎动物“凤姣昆明鱼”和“海口鱼” ,论证了普通无脊椎动物向脊椎动物演化过渡的各种中间类型 ,勾勒出一幅较为完整的早期生命演化谱系。西北大学早期生命研究所舒德干教授基于对靠近脊椎动物“源头”时段软躯体后口动物化石系列的研究以及新的发现提出脊椎动物起源分“五步走”的新假说 ,即在脊椎动物的起源的“四步走”前还有更为原始的“一步” :云南澄江出土的古虫动物门化石很可能代表了原口动物和后口动物间的过渡类型。本文即综述了普通无脊椎动物向脊椎动物演化的研究进展。     

埃迪卡拉纪至寒武纪苗岭世刺细胞动物化石研究现状与展望

刺细胞动物是一类具有刺细胞的水生无脊椎动物,分布在世界各地的海洋和淡水中。作为后生动物最早分化出的一支,刺细胞动物对研究后生动物的起源和早期演化具有极其重要的意义,也为研究后生动物系统发育、地层对比和古地理恢复等方面提供了重要的科研线索。本文简要介绍了刺细胞动物早期(埃迪卡拉纪至寒武纪苗岭世)的化石记录和研究现状,将刺细胞动物的早期演化分为四个时期,分别为前寒武纪、寒武纪纽芬兰世、寒武纪第二世和寒武纪苗岭世,并对上述四个时期的刺细胞动物进行论述。目前的研究表明:1)前寒武纪的刺细胞动物化石记录虽然比较丰富,但充满争议,目前尚未有比较确切的刺细胞动物记录;2)寒武纪纽芬兰世如宽川铺生物群中保存了较多的刺细胞动物胚胎及发育序列化石,是研究刺细胞动物演化的重要窗口;3)寒武纪第二世,以澄江生物群为代表的布尔吉斯页岩型化石保存了软躯体的刺细胞动物。与此同时,在第二世中已经出现了最早的珊瑚化石记录;4)寒武纪苗岭世刺细胞动物主要以布尔吉斯页岩型化石保存(如布尔吉斯页岩生物群和凯里生物群),同时期在美国犹他州发现的刺细胞动物印痕化石表明了这个时期几乎所有的刺细胞动物大类已经出现。本文根据上述时期的研究,对今后刺细胞动物化石的研究提供一些建议和讨论。     

Colour in Burgess Shale animals and the effect of light on evolution in the Cambrian

Diffraction gratings are reported from external surfaces of the hard, protective parts of Wiwaxia corrugata, Canadia spinosa and Marrella splendens from the Burgess Shale (Middle Cambrian (515 million years), British Columbia). As a consequence, these animals would have displayed iridescence in their natural environment: Cambrian animals have previously been accurately reconstructed in black and white only. A diversity of extant marine animals inhabiting a similar depth to the Burgess Shale fauna possess functional diffraction gratings. The Cambrian is a unique period in the history of animal life where predatory lifestyles and eyes capable of producing visual images were evolving rapidly. The discovery of colour in Cambrian animals prompts a new hypothesis on the initiation of the ''Big Bang'' in animal evolution which occurred during the Cambrian: light was introduced into the behavioural systems of metazoan animals for the first time. This introduction, of what was to become generally the most powerful stimulus in metazoan behavioural systems, would have triggered turbulence in metazoan evolution.     

Fossilized embryos are widespread but the record is temporally and taxonomically biased

We report new discoveries of embryos and egg capsules from the Lower Cambrian of Siberia, Middle Cambrian of Australia and Lower Ordovician of North America. Together with existing records, embryos have now been recorded from four of the seven continents. However, the new discoveries highlight secular and systematic biases in the fossil record of embryonic stages. The temporal window within which the embryos and egg capsules are found is of relatively short duration; it ends in the Early Ordovician and is roughly coincident with that of typical "Orsten"-type faunas. The reduced occurrence of such fossils has been attributed to reducing levels of phosphate in marine waters during the early Paleozoic, but may also be owing to the increasing depth of sediment mixing by infaunal metazoans. Furthermore, most records younger than the earliest Cambrian are of a single kind-large eggs and embryos of the priapulid-like scalidophoran Markuelia. We explore alternative explanations for the low taxonomic diversity of embryos recovered thus far, including sampling, size, anatomy, ecology, and environment, concluding that the preponderance of Markuelia embryos is due to its precocious development of cuticle at an embryonic stage, predisposing it to preservation through action as a substrate on which microbially mediated precipitation of authigenic calcium phosphate may occur. The fossil record of embryos may be limited to a late Neoproterozoic to early Ordovician snapshot that is subject to dramatic systematic bias. Together, these biases must be considered seriously in attempts to use the fossil record to arbitrate between hypotheses of developmental and life history evolution implicated in the origin of metazoan clades.     

Origin and evolution of animal life cycles

The ‘origin of larvae’ has been widely discussed over the years, almost invariably with the tacit understanding that larvae are secondary specializations of early stages in a holobenthic life cycle. Considerations of the origin and early radiation of the metazoan phyla have led to the conclusion that the ancestral animal (= metazoan) was a holopelagic organism, and that pelago-benthic life cycles evolved when adult stages of holopelagic ancestors became benthic, thereby changing their life style, including their feeding biology. The literature on the larval development and phylogeny of animal phyla is reviewed in an attempt to infer the ancestral life cycles of the major animal groups. The quite detailed understanding of larval evolution in some echinoderms indicates that ciliary filter-feeding was ancestral within the phylum, and that planktotrophy has been lost in many clades. Similarly, recent studies of the developmental biology of ascidians have demonstrated that a larval structure, such as the tail of the tadpole larva, can easily be lost, viz. through a change in only one gene. Conversely, the evolution of complex structures, such as the ciliary bands of trochophore larvae, must involve numerous genes and numerous adaptations. The following steps of early metazoan evolution have been inferred from the review. The holopelagic ancestor, blastaea, probably consisted mainly of choanocytes, which were the feeding organs of the organism. Sponges may have evolved when blastaea-like organisms settled and became reorganized with the choanocytes in collar chambers. The eumetazoan ancestor was probably the gastraea, as suggested previously by Haeckel. It was holopelagic and digestion of captured particles took place in the archenteron. Cnidarians and ctenophores are living representatives of this type of organization. The cnidarians have become pelago-benthic with the addition of a sessile, adult polyp stage; the pelagic gastraea-like planula larva is retained in almost all major groups, but only anthozoans have feeding larvae. Within the Bilateria, two major lines of evolution can be recognized: Protostomia and Deuterostomia. In protostomes, trochophores or similar types are found in most spiralian phyla; trochophore-like ciliary bands are found in some rotifers, whereas all other aschelminths lack ciliated larvae. It seems probable that the trochophore was the larval type of the ancestral, pelago-benthic spiralian and possible that it was ancestral in all protostomes. Most of the non-chordate deuterostome phyla have ciliary filter-feeding larvae of the dipleurula type, and this strongly indicates that the ancestral deuterostome had this type of larva.     

The mushroom bodies – prominent brain centres of arthropods and annelids with enigmatic evolutionary origin

Loesel, R. and Heuer, C.M. 2010. The mushroom bodies – prominent brain centres of arthropods and annelids with enigmatic evolutionary origin. —Acta Zoologica (Stockholm) 91 : 29–34 Mushroom bodies (MBs) are the most prominent and conspicuous neuropils in the brain of arthropods, onychophorans and vagile polychaete annelids but have not been described in any other animal group with complex brain architecture. Due to a number of unique neuroanatomical characters MBs can easily be identified and distinguished from other brain centres. However, their evolutionary origin and the question whether MBs are homologous structures is still under debate. This paper will briefly summarize the available morphological data and their implications with respect to the molecular evidence on early metazoan radiation. Unraveling the origin of MBs is an example of the challenges neurophylogenists will face in the future, especially so since it will signify a major step towards reconstructing early metazoan brain evolution.     

The Cambrian evolutionary 'explosion': decoupling cladogenesis from morphological disparity

The origin and differentiation of major clades is often assumed to have occurred in tandem with the 'explosion' of fossil evidence of diverse morphologies ('disparity') at the base of the Cambrian. Evidence is presented that this was not the case. Biogeographical and morphological differentiation among the earliest trilobites reveals incompleteness in the known early Cambrian record; similar evidence can be accrued for other major groups. Phylogenetic analysis proves the likelihood of 'ghost' lineages extending into the Precambrian. The important events in the generation of clades were earlier than the Cambrian 'explosion', at which time the groups become manifest in the fossil record. It is likely that the important phylogenetic changes happened in animals of small size; sister taxa of major groups are shown to be small animals. Decoupling cladogenesis from the Cambrian 'explosion' removes the necessity of invoking unknown evolutionary mechanisms at the base of the Phanerozoic. Genes controlling development may have played a role in generating new morphologies, through heterochrony for example, in the early differentiation of metazoan body plans.     

The origin of animal phyla and the new phylum Procoelomata

BergstrÖm, Jan 1989 07 15: The origin of animal phyla and the new phylum Procoelomata. Lethaia , Vol. 22, pp. 259–269. Oslo. ISSN 0024–1164.
A model of metazoan evolution presented previously (BergstrÖm 1986 in Zoologica Scripta 15 ) explains deuterostomian characters as derived from protostomian ones through loosening of the constraints in the spiralian type of morphogenesis. This fits phylogenies derived from studies of molecular sequences. The model helps explain (1) the well-known mixture of proto- and deuterostomian features in several groups; (2) the difficulties in making a phylogeny based on comparative anatomy, and (3) the fossil explosion in the Cambrian. Since protostomian features such as a ciliated locomotory sole and a pelagic larva with ciliary bands are widely distributed in branches of the phylogenetic tree, they must have been present in the stem of the tree. Most probably the stem forms were pseudosegmented, which helps explain how segmentation, oligomery and non-segmentation could evolve repeatedly in derived groups. Origination of new phyla involved macroevolutionary changes primarily in the mode of feeding and locomotion. The stem phylum, from which most other phyla appear to have been derived directly, is here named the Procoelomata. Machaeridian-type animals are referred to it. The Ediacaran-type Precambrian fossils Cannot be placed in the metazoan evolutionary tree. * Biochemical evolution, Cambrian fossil explosion, Deuterostomia, eukaryote evolution, Machaeridia. macroevolution, Precambrian fossils. Procoelomata, Protostomia .     

Receptor tyrosine kinase, an autapomorphic character of metazoa: identification in marine sponges

In the present review we summarize sequence data obtained from cloning of sponge receptor tyrosine kinases [RTK]. The cDNA sequences were mainly obtained from the marine sponge Geodia cydonium. RTKs (i) with immunoglobulin [Ig]-like domains in the extracellular region, (ii) of the type of insulin-like receptors, as well as (iii) RTKs with one extracellular speract domain, have been identified. The analyses revealed that the RTK genes are constructed in blocks [domains], suggesting a blockwise evolution. The phylogenetic relationships of the sequences obtained revealed that all sponge sequences fall into one branch of the evolutionary tree, while related sequences from higher Metazoa, human, mouse and rat, including also invertebrate sequences, together form a second branch. It is concluded that the RTK molecules have evolved in sponges prior to the "Cambrian Explosion" and have contributed to the rapid appearance of the higher metazoan phyla and that sponges are, as a taxon, also monophyletic. Due to the fact that protein tyrosine kinases in general and RTKs in particular have only been identified in Metazoa, they are, as a group qualified, to be considered as an autapomorphic character of all metazoan phyla.     

陕南寒武系底部磷酸盐化保存的寒武松藻属化石新知

本文描述了产于我国陕西西乡寒武系底部磷矿层中的藻类化石,在标本中发现多种藻枝保存类型和可能的"固着器"等特征;由于藻体微小、藻管中空等特征而将其归入蓝菌类寒武松藻属;可为早寒武世早期的藻类繁盛提供了新的小生境和新的食物来源、加速了后生动物的进化。