The Hox Paradox: More complex(es) than imagined

An understanding of the origin of different body plans requires knowledge of how the genes and genetic pathways that control embryonic development have evolved. The Hox genes provide an appealing starting point for such studies because they play a well-understood causal role in the regionalization of the body plan of all bilaterally symmetric animals. Vertebrate evolution has been characterized by gene, and possibly genome, duplication events, which are believed to have provided raw genetic material for selection to act upon. It has recently been established that the Hox gene organization of ray-finned fishes, such as the zebrafish, differs dramatically from that of their lobe-finned relatives, a group that includes humans and all the other widely used vertebrate model systems. This unusual Hox gene organization of zebrafish is the result of a duplication event within the ray-finned fish lineage. Thus, teleosts, such as zebrafish, have more Hox genes arrayed over more clusters (or "complexes") than do tetrapod vertebrates. Here, I review our understanding of Hox cluster architecture in different vertebrates and consider the implications of gene duplication for Hox gene regulation and function and the evolution of different body plans.     

The amphioxus Hox cluster: deuterostome posterior flexibility and Hox14

SUMMARY The amphioxus ( Branchiostoma floridae ) Hox cluster is a model for the ancestral vertebrate cluster, prior to the hypothesized genome-wide duplications that may have facilitated the evolution of the vertebrate body plan. Here we describe the posterior (5') genes of the amphioxus cluster, and report the isolation of four new homeobox genes. Vertebrates possess 13 types of Hox gene (paralogy groups), but we show that amphioxus possesses more than 13 Hox genes. Amphioxus is now the first animal in which a Hox14 gene has been found. Our mapping and phylogenetic analysis of amphioxus "Posterior Class" Hox genes reveals that these genes are evolving at a faster rate in deuterostomes than in protostomes, a phenomenon we term Posterior Flexibility.     

基因倍增和脊椎动物起源

有机体基因复制导致基因复杂性增加及其和脊椎动物起源的关系已经成为进化生物学研究的热点。20世纪70年代由Ohno提出后经Holland等修正的原始脊索动物经两轮基因组复制产生脊椎动物的假设目前已被广泛接受。脊椎动物起源和进化过程中发生过两轮基因组复制的主要证据有三点：（1）据估计脊椎动物基因组内编码基因数目大约相当于果蝇、海鞘等无脊椎动物的4倍;原口动物如果蝇和后口动物如头索动物文昌鱼的基因组大都只有单拷贝的基因,而脊椎动物的基因组则通常有4个同属于一个家族的基因。（2）无脊椎动物如节肢动物、海胆和头索动物文昌鱼都只有一个Hox基因簇,而脊椎动物除鱼类外,有7个具有Hox基因簇,其余都具有4个Hox基因簇。（3）基因作图证明,不但在鱼类和哺乳动物染色体广大片段上基因顺序相似,而且有证据显示哺乳动物基因组不同染色体之间存在相似性。据认为第一次基因倍增发生在脊椎动物与头索动物分开之后,第二次基因倍增发生在有颌类脊椎动物和无颌类脊椎动物分开以后。但是,基因是逐个发生倍增,还是通过基因组内某些DNA片段抑或整个基因组的加倍而实现的,目前还颇有争议。     

2R or not 2R: Testing hypotheses of genome duplication in early vertebrates

The widely popular hypothesis that there were two rounds of genome duplication by polyploidization early in vertebrate history (the 2R hypothesis) has been difficult to test until recently. Among the lines of evidence adduced in support of this hypothesis are relative genome size, relative gene number, and the existence of genomic regions putatively duplicated during polyploidization. The availability of sequence for a substantial portion of the human genome makes possible the first rigorous tests of this hypothesis. Comparison of gene family size in the human genome and in invertebrate genomes shows no evidence of a 4:1 ratio between vertebrates and invertebrates. Furthermore, explicit phylogenetic tests for the topology expected from two rounds of polyploidization have revealed alternative topologies in a substantial majority of human gene families. Likewise, phylogenetic analyses have shown that putatively duplicated genomic regions often include genes duplicated at widely different times over the evolution of life. The 2R hypothesis thus can be decisively rejected. Rather, current evidence favors a model of genome evolution in which tandem duplication, whether of genomic segments or of individual genes, predominates.     

From genomes to morphology: a view from amphioxus

Holland, P.W.H. 2010. From genomes to morphology: a view from amphioxus. —Acta Zoologica (Stockholm) 91 : 81–86 As complete genome sequences are determined from an ever‐increasing number of animal species, new opportunities are arising for comparative biology. For zoologists interested in the evolution of shape and form, however, there is a problem. The link between genome sequence and morphology is not direct and is obfuscated by complex and evolving genetic pathways, even when conserved regulatory genes are considered. Nonetheless, a large‐scale comparison of genome sequences between extant chordates reveals an intriguing parallel between genotypic and phenotypic evolution. Tunicates have highly altered genomes, with loss of ancestral genes and shuffled genetic arrangements, while vertebrate genomes are also derived through gene loss and genome duplication. The recently sequenced amphioxus genome, in contrast, reveals much greater stasis on the cephalochordate lineage, in parallel to a less derived body plan. The opportunities and challenges for relating genome evolution to morphological evolution are discussed.     

A dynamic history of gene duplications and losses characterizes the evolution of the SPARC family in eumetazoans

The vertebrates share the ability to produce a skeleton made of mineralized extracellular matrix. However, our understanding of the molecular changes that accompanied their emergence remains scarce. Here, we describe the evolutionary history of the SPARC (secreted protein acidic and rich in cysteine) family, because its vertebrate orthologues are expressed in cartilage, bones and teeth where they have been proposed to bind calcium and act as extracellular collagen chaperones, and because further duplications of specific SPARC members produced the small calcium-binding phosphoproteins (SCPP) family that is crucial for skeletal mineralization to occur. Both phylogeny and synteny conservation analyses reveal that, in the eumetazoan ancestor, a unique ancestral gene duplicated to give rise to SPARC and SPARCB described here for the first time. Independent losses have eliminated one of the two paralogues in cnidarians, protostomes and tetrapods. Hence, only non-tetrapod deuterostomes have conserved both genes. Remarkably, SPARC and SPARCB paralogues are still linked in the amphioxus genome. To shed light on the evolution of the SPARC family members in chordates, we performed a comprehensive analysis of their embryonic expression patterns in amphioxus, tunicates, teleosts, amphibians and mammals. Our results show that in the chordate lineage SPARC and SPARCB family members were recurrently recruited in a variety of unrelated tissues expressing collagen genes. We propose that one of the earliest steps of skeletal evolution involved the co-expression of SPARC paralogues with collagenous proteins.     

Diversity and evolution of MicroRNA gene clusters

microRNA (miRNA) gene clusters are a group of miRNA genes clustered within a proximal distance on a chromosome. Although a large number of miRNA clusters have been uncovered in animal and plant genomes, the functional consequences of this arrangement are still poorly understood. Located in a polycistron, the coexpressed miRNA clusters are pivotal in coordinately regulating multiple processes, including embryonic development, cell cycles and cell differentiation. In this review, based on recent progress, we discuss the genomic diversity of miRNA gene clusters, the coordination of expression and function of the clustered miRNAs, and the evolutionarily adaptive processes with gain and loss of the clustering miRNA genes mediated by duplication and transposition events. Supported by State Key Program of National Natural Science of China(Grant No. 306300130)     

The temporal distribution of gene duplication events in a set of highly conserved human gene families

Using a data set of protein translations associated with map positions in the human genome, we identified 1520 mapped highly conserved gene families. By comparing sharing of families between genomic windows, we identified 92 potentially duplicated blocks in the human genome containing 422 duplicated members of these families. Using branching order in the phylogenetic trees, we timed gene duplication events in these families relative to the primate-rodent divergence, the amniote-amphibian divergence, and the deuterostome-protostome divergence. The results showed similar patterns of gene duplication times within duplicated blocks and outside duplicated blocks. Both within and outside duplicated blocks, numerous duplications were timed prior to the deuterostome-protostome divergence, whereas others occurred after the amniote-amphibian divergence. Thus, neither gene duplication in general nor duplication of genomic blocks could be attributed entirely to polyploidization early in vertebrate history. The strongest signal in the data was a tendency for intrachromosomal duplications to be more recent than interchromosomal duplications, consistent with a model whereby tandem duplication-whether of single genes or of genomic blocks-may be followed by eventual separation of duplicates due to chromosomal rearrangements. The rate of separation of tandemly duplicated gene pairs onto separated chromosomes in the human lineage was estimated at 1.7 x 10(-9) per gene-pair per year.     

The fates of zebrafish Hox gene duplicates

In his 1970 book, Susumu Ohno stressed the importance of gene duplication in the evolution of the vertebrate genome and body plan. He elaborated the idea that duplication events provide novel genetic material on which evolution may act. Data are accumulating to show that extensive duplication events, perhaps incorporating the duplication of entire genomes, occurred in the lineage leading to teleost fishes. These duplications may have been pivotal in the explosive radiation of this highly successful vertebrate group. Thus, the teleosts provide us with an ideal opportunity to investigate the fates and functions of duplicated genes. A convenient system for these studies is the zebrafish, Danio rerio, which has become a popular genetic and embryological model.     

The "fish-specific" Hox cluster duplication is coincident with the origin of teleosts

The Hox gene complement of zebrafish, medaka, and fugu differs from that of other gnathostome vertebrates. These fishes have seven to eight Hox clusters compared to the four Hox clusters described in sarcopterygians and shark. The clusters in different teleost lineages are orthologous, implying that a "fish-specific" Hox cluster duplication has occurred in the stem lineage leading to the most recent common ancestor of zebrafish and fugu. The timing of this event, however, is unknown. To address this question, we sequenced four Hox genes from taxa representing basal actinopterygian and teleost lineages and compared them to known sequences from shark, coelacanth, zebrafish, and other teleosts. The resulting gene genealogies suggest that the fish-specific Hox cluster duplication occurred coincident with the origin of crown group teleosts. In addition, we obtained evidence for an independent Hox cluster duplication in the sturgeon lineage (Acipenseriformes). Finally, results from HoxA11 suggest that duplicated Hox genes have experienced diversifying selection immediately after the duplication event. Taken together, these results support the notion that the duplicated Hox genes of teleosts were causally relevant to adaptive evolution during the initial teleost radiation.     

Telomeres and telomerase: more than the end of the line

Early studies of telomerase suggested that telomeres are maintained by an elegant but relatively simple and highly conserved mechanism of telomerase-mediated replication. As we learn more, it has become clear that the mechanism is elegant but not as simple as first thought. It is also evident that, although many species use similar, sometimes identical, DNA sequences for telomeres, these species express their own individuality in the way they regulate these sequences and, perhaps, in the additional tasks that they have imposed on their telomeric DNA. The striking similarities between telomeres in different species have revealed much about chromosome ends; the differences are proving to be equally informative. In addition to the differences between species that use telomerase, there are also a few exceptional organisms with atypical telomeres for which no telomerase activity has been detected. This review addresses recent studies, the insights they offer, and, perhaps more importantly, the questions they raise. Received: 14 January 1999 / Accepted: 15 January 1999     

重复基因的进化一回顾与进展

基因重复是普遍存在的生物学现象, 是基因组和遗传系统多样化的重要推动力量, 在生物进化过程中发挥着极其重要的作用。基因重复有何利弊, 基因发生重复后, 2个重复子拷贝的保留在基因功能方面是否存在偏好性, 子拷贝在表达和进化速率上如何分化, 以及重复基因为什么会被保留下来一直是进化生物学领域研究的热点问题之一。该文对以上重复基因研究的热点问题进行了介绍, 并对重复基因的进化机制和理论模型及其近年来的一些主要研究进展进行了综述。     

脊椎动物基因组与基因复制研究进展

脊椎动物的出现是动物进化历史上一次质的飞跃.由于所有的脊椎动物在其胚胎发育中都呈现连续的解剖学特征,因此过去很多学者都根据现存脊椎动物的形态特征和在其发育过程中的解剖学特征假想原始脊椎动物,并推导其进化过程和起源.近年来的研究表明,通过对脊椎动物和与之亲缘关系接近的物种之间进行基因家族、染色体结构分析,可以对脊椎动物进化提供很多线索和证据.更多的研究表明,脊椎动物在进化过程中很可能发生过整体基因组的复制, 基因和/或基因组的复制可能是引起脊椎动物形体结构复杂性增加的根本原因.因此,基因和基因组的复制正在成为生物进化研究的热点问题.但这两种复制方式中哪一种是产生动物形体结构和功能复杂性增加最重要的原因尚有争论.     

应用PRINS技术定位黄鳝Hox基因的研究

Hox基因是近年来发现的支持基因组复制进化理论的最有力的证据。该研究应用引物原位延伸 (PRINS)技术 ,在黄鳝有丝分裂染色体标本上开展Hox基因的定位研究。研究结果表明 ,在黄鳝染色体组中可能存在有 6个Hox基因簇 ,这些基因簇分别位于黄鳝第 1、2、3、6、8和 10号染色体 ,相对着丝粒距离分别为 2 8 2 4± 2 88、4 5 5±1 39、13 89± 2 0 3、74 32± 1.86、38 0 3± 2 .4 1和 5 8 18± 2 0 5。该研究定位黄鳝Hox基因将有助于挖掘黄鳝染色体的来源和进化特征 ,并为基因组复制进化理论提供黄鳝这一特化物种的细胞遗传学证据。     

The major tick salivary gland proteins and toxins from the soft tick,Ornithodoros savignyi,are part of the tick Lipocalin family: implications for the origins of tick toxicoses

The origins of tick toxicoses remain a subject of controversy because no molecular data are yet available to study the evolution of tick-derived toxins. In this study we describe the molecular structure of toxins from the soft tick, Ornithodoros savignyi. The tick salivary gland proteins (TSGPs) are four highly abundant proteins proposed to play a role in salivary gland granule biogenesis of the soft tick O. savignyi, of which the toxins TSGP2 and TSGP4 are a part. They were assigned to the lipocalin family based on sequence similarity to known tick lipocalins. Several other tick lipocalins were also identified using Smith-Waterman database searches, bringing the tick lipocalin family up to 20. Phylogenetic analysis showed that most tick lipocalins group within genus-specific clades, suggesting that gene duplication and divergence of tick lipocalin function occurred after tick speciation, most probably during the evolution of a hematophagous lifestyle. TSGP2 and TSGP3 show high sequence identity and group terminal to moubatin, an inhibitor of collagen-induced platelet aggregation from the tick, O. moubata. However, no platelet aggregation inhibitory activity is associated with the TSGPs using ADP or collagen as agonists, suggesting that TSGP2 and TSGP3 duplicated after divergence of O. savignyi and O. moubata. This timing is supported by the absence of TSGP2-4 in the salivary gland extracts of O. moubata. The absence of TSGP2 and TSGP4 in salivary gland extracts from O. moubata correlates with the nontoxicity of this tick species. The implications of this study are that the various forms of tick toxicoses do not have a common origin, but must have evolved independently in those tick species that cause pathogenesis.     

脊椎动物ABCA基因亚家族研究进展

ABC（ATP-binding cassette）基因家族编码膜蛋白,其成员负责多种物质的跨膜运输。基于氨基酸序列的同源性,人的48个ABC成员被分为7个亚家族：ABCA~ABCG。与其他亚家族相比,ABCA基因编码的蛋白具有独特的拓扑结构,并且其家族成员在两栖动物和哺乳动物分化之后各发生过一次大的扩展（expanding）。基因结构分析发现这两次扩展均是通过基因倍增实现的,这些倍增的产物在啮齿目和食肉目中得到保留,而在灵长目中却有一半变成假基因或被删除。ABCA成员主要负责不同组织器官脂类和胆固醇的跨膜运输,部分成员的突变与疾病相关。