Body size,duration of parental care,and the intrinsic rate of natural increase in eutherian and metatherian mammals

Summary The intrinsic rate of natural increase (r _m), conception to weaning time (t _cw), age of first reproduction (t_mat), and components of fecundity were compared between ecologically similar groups of 42 metatherian (=marsupial) and 42 eutherian mammals. Marsupial t _cw s average 50% longer than those of eutherians. Small marsupials (<400 g) mature later, and have lower and r _ms than eutherians; large marsupials (>10,000 g) do not mature later but also have lower r _ms. At body sizes of 1,000–3,500 g, marsupials and eutherians have similar t _mat s and t _cw s but marsupials have greater r _ms. Marsupials compensate for their longer t _cw s by a variety of methods including embryonic diapause, larger litter sizes, and short periods between weaning and maturity. Although the greatest similarities in marsupial and eutherian life histories are at body sizes of 1–5 kg, compensation for long t _cw may be seen at any marsupial body size. Other ecological factors not withstanding, marsupial reproduction is neither inherently inferior to that of eutherians nor obviously more advantageous in unpredictable environs.     

The karyotype of Alligator mississippiensis,and chromosomal mapping of the ZFY/X homologue,Zfc

Comparative mapping studies of X-linked genes in mammals have provided insights into the evolution of the X chromosome. Many reptiles including the American alligator, Alligator mississippiensis, do not appear to possess heteromorphic sex chromosomes, and sex is determined by the incubation temperature of the egg during embryonic development. Mapping of homologues of mammalian X-linked genes in reptiles could lead to a greater understanding of the evolution of vertebrate sex chromosomes. One of the genes used in the mammalian mapping studies was ZFX, an X-linked copy of the human ZFY gene which was originally isolated as a candidate for the mammalian testis-determining factor (TDF). ZFX is X-linked in eutherians, but maps to two autosomal locations in marsupials and monotremes, close to other genes associated with the eutherian X. The alligator homologue of the ZFY/ZFX genes, Zfc, has been isolated and described previously. A detailed karyotype of A. mississippiensis is presented, together with chromosomal in situ hybridisation data localising the Zfc gene to chromosome 3. Further chromosomal mapping studies using eutherian X-linked genes may reveal conserved chromosomal regions in the alligator that have become part of the eutherian X chromosome during evolution.     

In silico identification of opossum cytokine genes suggests the complexity of the marsupial immune system rivals that of eutherian mammals

Background

Cytokines are small proteins that regulate immunity in vertebrate species. Marsupial and eutherian mammals last shared a common ancestor more than 180 million years ago, so it is not surprising that attempts to isolate many key marsupial cytokines using traditional laboratory techniques have been unsuccessful. This paucity of molecular data has led some authors to suggest that the marsupial immune system is 'primitive' and not on par with the sophisticated immune system of eutherian (placental) mammals.

Results

The sequencing of the first marsupial genome has allowed us to identify highly divergent immune genes. We used gene prediction methods that incorporate the identification of gene location using BLAST, SYNTENY + BLAST and HMMER to identify 23 key marsupial immune genes, including IFN-γ, IL-2, IL-4, IL-6, IL-12 and IL-13, in the genome of the grey short-tailed opossum (Monodelphis domestica). Many of these genes were not predicted in the publicly available automated annotations.

Conclusion

The power of this approach was demonstrated by the identification of orthologous cytokines between marsupials and eutherians that share only 30% identity at the amino acid level. Furthermore, the presence of key immunological genes suggests that marsupials do indeed possess a sophisticated immune system, whose function may parallel that of eutherian mammals.     

Mammalian genome evolution: new clues from comparisons of eutherians, marsupials and monotremes.

1. Comparisons of chromosomes and gene maps of different mammals are yielding a big picture of the evolution of mammalian genome form and function. It has been particularly instructive to compare gene arrangements on the sex chromosomes between the three major groups of mammals. Eutheria (so-called placental mammals). Metatheria (marsupials) and Prototheria (monotremes), which diverged 150 and 170 Myr BP respectively. 2. A region amounting to 3% of the haploid genome is located on the X chromosome in all three groups, implying that this region must have been part of the original X in a common ancestor. This region comprises the long arm of the human X. 3. A region represented by the short arm of the human X is common to the X in all eutherians, but is autosomal in marsupials and monotremes; thus it was not a part of the original X, and must have been acquired by the X early in the eutherian radiation. 4. This recently acquired region was probably translocated to a pseudoautosomal region shared by the eutherian X and Y. Thus it was originally paired and exempt from X chromosome inactivation; stepwise deletion of this region from the Y and recruitment of the newly unpaired region of the X into the inactivation system could account for some of the peculiarities of this region of the human X. 5. The sex-determining gene TDF must lie on the Y in all mammals in which the Y is male determining. The autosomal location of the candidate gene ZFY in marsupials and monotremes eliminates it from consideration. The recently described candidate gene SRY has yet to pass the "marsupial test".     

Marsupial MHC class II beta genes are not orthologous to the eutherian beta gene families

The major histocompatibility complex (MHC) class II DRB, DQB, DPB, and DOB gene clusters are shared by different eutherian orders. Such an orthologous relationship is not seen between the beta genes of birds and eutherians. A high degree of uncertainty surrounds the evolutionary relationship of marsupial class II beta sequences with eutherian beta gene families. In particular, it has been suggested that marsupials utilize the DRB gene cluster. A cDNA encoding an MHC class II beta molecule was isolated from a brushtail possum mesenteric lymph node cDNA library. This clone is most similar to Macropus rufogriseus DBB. Our analysis suggests that all known marsupial beta-chain genes, excluding DMB, fall into two separate clades, which are distinct from the eutherian DRB, DQB, DPB, or DOB gene clusters. We recommend that the DAB and DBB nomenclature be reinstated. DAB and DBB orthologs are not present in eutherians. It appears that the marsupial and eutherian lineages have retained different gene clusters following gene duplication events early in mammalian evolution.     

Mapping human X-linked genes in the phalangerid marsupial Trichosurus vulpecula.

We mapped 15 human X-chromosome markers in the common brush-tailed possum, Trichosurus vulpecula (Kerr), which represents the Australian marsupial family Phalangeridae. In situ hybridization was used to localize highly conserved human X-linked genes to chromosomes of T. vulpecula diploid lines. Ten genes located on the long arm of the human X (human Xq genes) all mapped to the possum X chromosome. However, all five genes located on the short arm of the human X (human Xp genes) mapped to autosomes. These findings confirm our previous work, which showed that the X chromosome in macropodid and dasyurid marsupials bears all the human Xq genes but none of the human Xp genes studied. This suggests that the marsupial X is highly conserved, but its gene content reflects that of only part of the eutherian X, a result consistent with our hypothesis that an autosomal region was added to the X early in eutherian divergence.     

Genes on the short arm of the human X chromosome are not shared with the marsupial X.

Eight genes located on the short arm of the human X chromosome (MAOA, SYN1, OAT, OTC, CYBB, DMD, ZFX, POLA) have been mapped in several marsupial species by cell hybrid analysis and/or in situ hybridization using probes derived from human cDNA. Seven appear to be autosomal in all marsupial species examined. The eighth, CYBB, detected a site on the X, as well as major autosomal sites. Although these genes are not conserved on the X chromosome in marsupials, at least some of them are arranged together in autosomal clusters. The autosomal location of human Xp genes in marsupials could mean that this region either was lost from a large ancestral X chromosome in the marsupial lineage or was acquired by a small ancestral X (and perhaps Y) in the eutherian lineage. Either explanation demands that the region was not subject to X chromosome inactivation in a common ancestor 120-150 MyrBP.     

Shared DNA sequences between the X and Y chromosomes in the tammar wallaby – evidence for independent additions to eutherian and marsupial sex chromosomes

Marsupial sex chromosomes are smaller than their eutherian counterparts and are thought to reflect an ancestral mammalian X and Y. The gene content of this original X is represented largely by the long arm of the human X chromosome. Genes on the short arm of the human X are autosomal in marsupials and monotremes, and represent a recent addition to the eutherian X and Y. The marsupial X and Y apparently lack a pseudoautosomal region and show only end-to-end pairing at meiosis. However, the sex chromosomes of macropodid marsupials (kangaroos and wallabies) are larger than the sex chromosomes of other groups, and a nucleolus organizer is present on the X and occasionally the Y. Chromosome painting using DNA from sorted and microdissected wallaby X and Y chromosomes reveals homologous sequences on the tammar X and Y chromosomes, concentrated on the long arm of the Y chromosome and short arm of the X. Ribosomal DNA sequences were detected by fluorescence in situ hybridization on the wallaby Xp but not the Y. Since no chiasmata have been observed in marsupial sex chromosomes, it is unlikely that these shared sequences act as a pseudoautosomal region within which crossing over may occur, but they may be required for end-to-end associations. The shared region of wallaby X and Y chromosomes bears no homology with the recently added region of the eutherian sex chromosomes, so we conclude that independent additions occurred to both sex chromosomes in a eutherian and macropodid ancestor, as predicted by the addition-attrition hypothesis of sex chromosome evolution. Received: 18 October 1996 / Accepted: 21 February 1997     

No Evidence for a Second Evolutionary Stratum during the Early Evolution of Mammalian Sex Chromosomes

Mammalian sex chromosomes originated from a pair of autosomes, and homologous genes on the sex chromosomes (gametologs) differentiated through recombination arrest between the chromosomes. It was hypothesized that this differentiation in eutherians took place in a stepwise fashion and left a footprint on the X chromosome termed “evolutionary strata.” The evolutionary stratum hypothesis claims that strata 1 and 2 (which correspond to the first two steps of chromosomal differentiation) were generated in the stem lineage of Theria or before the divergence between eutherians and marsupials. However, this prediction relied solely on the molecular clock hypothesis between pairs of human gametologs, and molecular evolution of marsupial sex chromosomal genes has not yet been investigated. In this study, we analyzed the following 7 pairs of marsupial gametologs, together with their eutherian orthologs that reside in stratum 1 or 2: SOX3/SRY, RBMX/Y, RPS4X/Y, HSFX/Y, XKRX/Y, SMCX/Y (KDM5C/D, JARID1C/D), and UBE1X/Y (UBA1/UBA1Y). Phylogenetic analyses and estimated divergence time of these gametologs reveal that they all differentiated at the same time in the therian ancestor. We have also provided strong evidence for gene conversion that occurred in the 3′ region of the eutherian stratum 2 genes (SMCX/Y and UBE1X/Y). The results of the present study show that (1) there is no compelling evidence for the second stratum in the stem lineage of Theria; (2) gene conversion, which may have occurred between SMCX/Y and UBE1X/Y in the eutherian lineage, potentially accounts for their apparently lower degree of overall divergence.     

Absence of adaptive nonshivering thermogenesis in a marsupial,the fat-tailed dunnart (<Emphasis Type="Italic">Sminthopsis crassicaudata</Emphasis>)

The presence of nonshivering thermogenesis in marsupials is controversially debated. Survival of small eutherian species in cold environments is crucially dependent on uncoupling protein 1 (UCP1)-mediated, adaptive nonshivering thermogenesis that is executed in brown adipose tissue. In a small dasyurid marsupial species, the fat-tailed dunnart (Sminthopsis crassicaudata), an orthologue of UCP1 has been recently identified which is upregulated during cold exposure resembling adaptive molecular adjustments of eutherian brown adipose tissue. Here, we tested for a thermogenic function of marsupial brown adipose tissue and UCP1 by evaluating the capacity of nonshivering thermogenesis in cold-acclimated dunnarts. In response to an optimal dosage of noradrenaline, cold-acclimated dunnarts (12°C) showed no additional recruitment of noradrenaline-induced maximal thermogenic capacity in comparison to warm-acclimated dunnarts (24°C). While no differences in body temperature were observed between the acclimation groups, basal metabolic rate was significantly elevated after cold acclimation. Therefore, we suggest that adaptive nonshivering thermogenesis does not occur in this marsupial species despite the cold recruitment of oxidative capacity and UCP1 in the interscapular fat deposit. In conclusion, the ancient UCP orthologue in marsupials does not contribute to the classical nonshivering thermogenesis, and may exhibit a different physiological role.     

Gene mapping in marsupials and monotremes

Somatic cell genetic mapping of marsupial and monotreme species will greatly extend the power of comparative gene mapping to detect ancient mammalian gene arrangements. The use of eutherian-marsupial cell hybrids for such mapping is complicated by the frequent retention of deleted and rearranged marsupial chromosomes. We used staining techniques, involving the fluorochromes Hoechst 33258 and chromomycin A₃, to facilitate rapid and unequivocal identification of marsupial chromosomes and chromosome segments and to make chromosome assignment and regional localization of marsupial genes possible. Chromosome segregation in rodent-macropod hybrids was consistent with preferential loss of the marsupial complement. The extent of loss was very variable. Some hybrids retained 30% of the marsupial complement; some retained small centric fragments; and some, no cytologically identifiable marsupial material. We examined the chromosomes and gene products of a number of rodent-grey kangaroo Macropus giganteus hybrids, and have assigned the genes Pgk-A (phosphoglycerate kinase-A), Hpt (Hypoxanthine phosphoribosyl transferase), and Gpd (Glucose-6-phosphate dehydrogenase) to the long arm of the kangaroo X chromosome, and provisionally established the gene order Pgk-A -Hpt -Gpd.     

The α-Globin Gene Family of an Australian Marsupial, Macropus eugenii: The Long Evolutionary History of the θ-Globin Gene and Its Functional Status in Mammals

Comparative evolutionary analyses of gene families among divergent lineages can provide information on the order and timing of major gene duplication events and evolution of gene function. Here we investigate the evolutionary history of the α-globin gene family in mammals by isolating and characterizing α-like globin genes from an Australian marsupial, the tammar wallaby, Macropus eugenii. Sequence and phylogenetic analyses indicate that the tammar α-globin family consists of at least four genes including a single adult-expressed gene (α), two embryonic/neonatally expressed genes (ζ and ζ′), and θ-globin, each orthologous to the respective α-, ζ-, and θ-globin genes of eutherian mammals. The results suggest that the θ-globin lineage arose by duplication of an ancestral adult α-globin gene and had already evolved an unusual promoter region, atypical of all known α-globin gene promoters, prior to the divergence of the marsupial and eutherian lineages. Evolutionary analyses, using a maximum likelihood approach, indicate that θ-globin, has evolved under strong selective constraints in both marsupials and the lineage leading to human θ-globin, suggesting a long-term functional status. Overall, our results indicate that at least a four-gene cluster consisting of three α-like and one β-like globin genes linked in the order 5′–ζ–α–θ–ω–3′ existed in the common ancestor of marsupials and eutherians. However, results are inconclusive as to whether the two tammar ζ-globin genes arose by duplication prior to the radiation of the marsupial and eutherian lineages, with maintenance of exon sequences by gene conversion, or more recently within marsupials.Reviewing Editor: Dr. John Oakeshott     

Cardiovascular characteristics of two resting marsupials: An insight into the cardio-respiratory allometry of marsupials

Summary Minimum resting values for several cardiovascular and respiratory characteristics were established for two marsupial species,Trichosurus vulpecula andMacropus eugenii. Certain characteristics including heart rate, stroke volume and cardiac output varied significantly with body mass and allometric equations of the formy=aM ^b were derived to describe the relationships. The exponents of body mass,b, were generally similar to those for eutherian mammals, but in the marsupials they intercept,a, differed significantly from reported eutherian values.Although resting cardiac output in the marsupials appeared reduced in proportion to their lower resting oxygen consumption this pattern was not repeated for other variables. The stroke volume of the marsupials was 156% of eutherian levels while heart rate was less than 50% of the eutherian values.Initial data for respiratory variables also indicated comparable differences in this aspect of oxygen transport between marsupials and eutherians. Minimum respiratory rates of the marsupials were much lower than those of eutherians and tidal volumes appear larger in marsupials. The results are interpreted as suggesting that marsupials may have a large aerobic capacity.     

Autosomal localization of the amelogenin gene in monotremes and marsupials: implications for mammalian sex chromosome evolution.

We have determined by Southern blot analysis that DNA sequences homologous to the AMG gene probe are present in the genomes of both marsupial and monotreme mammals, although adult monotremes lack teeth. In situ hybridization and Southern analysis of cell hybrids demonstrate that AMG homologues are located on autosomes. In the Tammar Wallaby, AMG homologues are located on chromosomes 5q and 1q and in the Platypus, on chromosomes 1 and 2. The autosomal location of the AMG homologues provides additional support for the hypothesis that an autosomal region equivalent to the human Xp was translocated to the X chromosome in the Eutheria after the divergence of the marsupials 150 million years ago. The region containing the AMG gene is therefore likely to have been added 80-150 million years ago to a pseudoautosomal region shared by the ancestral eutherian X and Y chromosome; the X and Y alleles must have begun diverging after this date.     

A VpreB3 homologue in a marsupial, the gray short-tailed opossum, Monodelphis domestica

A VpreB surrogate light (SL) chain was identified for the first time in a marsupial, the opossum Monodelphis domestica. Comparing the opossum VpreB to homologues from eutherian (placental mammals) and avian species supported the marsupial gene being VpreB3. VpreB3 is a protein that is not known to traffic to the cell surface as part of the pre-B cell receptor. Rather, VpreB3 associates with nascent immunoglobulin chains in the endoplasmic reticulum. Homologues of other known SL chains VpreB1, VpreB2, and λ5, which are found in eutherian mammals, were not found in the opossum genome, nor have they been identified in the genomes of nonmammals. VpreB3 likely evolved from earlier gene duplication, independent of that which generated VpreB1 and VpreB2 in eutherians. The apparent absence of VpreB1, VpreB2, and λ5 in marsupials suggests that an extracellular pre-B cell receptor containing SL chains, as it has been defined in humans and mice, may be unique to eutherian mammals. In contrast, the conservation of VpreB3 in marsupials and its presence in nonmammals is consistent with previous hypotheses that it is playing a more primordial role in B cell development.