Effects of the lethal yellow (Ay) mutation in mouse aggregation chimeras

The Ay allele is a recessive lethal mutation at the mouse agouti locus, which results in embryonic death around the time of implantation. In the heterozygous state, Ay produces several dominant pleiotropic effects, including an increase in weight gain and body length, a susceptibility to hepatic, pulmonary and mammary tumors, and a suppression of the agouti phenotype, which results in a yellow coat color. To investigate the cellular action of Ay with regard to its effects upon embryonic viability and adult-onset obesity, we generated a series of aggregation chimeras using embryos that differ in their agouti locus genotype. Embryos derived from Ay/a x Ay/a matings were aggregated with those derived from A/A x A/A matings, and genotypic identification of the resultant chimeras was accomplished using a molecular probe at the Emv-15 locus that distinguishes among the three different alleles, Ay, A, and a. Among 50 chimeras, 25 analyzed as liveborns and 25 as 9.5 day embryos, 29 were a/a in equilibrium A/A and 21 were Ay/a in equilibrium A/A. The absence of Ay/Ay in equilibrium A/A chimeras demonstrates that Ay/Ay cells cannot be rescued in a chimeric environment, and the relative deficiency of Ay/a in equilibrium A/A chimeras suggests that, under certain conditions, Ay heterozygosity may partially affect cell viability or proliferation. In the 25 liveborn chimeras, Ay/a in equilibrium A/A animals became obese as adults and a/a in equilibrium A/A animals did not. There was no correlation between genotypic proportions and rate of weight gain, which shows that, with regard to its effects on weight gain, Ay heterozygosity is cell non-autonomous.     

Combining sperm plug genotyping and coat color chimerism predicts germline transmission

There has been a significant increase in the use of C57BL/6N-derived ES cells for the production of gene knockout mice. However, the potential for germline transmission (GLT) from chimeras on this genetic background has been observed to be highly variable. Using coat color as an indicator of somatic chimerism to infer the extent of chimeric contribution to the germ cell population, even highly agouti C57BL/6N-derived chimeras can fail to achieve GLT. We investigated the extent to which quantitative PCR genotyping for a marker gene expressed in gene targeted ES cells can be performed on DNA extracted from sperm present in copulatory plugs to determine the contribution of ES cells to the germ cells. We found that an objective assessment of sperm DNA from copulatory plugs combined with a subjective assessment of coat color chimerism can be used to accurately inform the selection of chimeras for breeding that are likely to achieve GLT. These results indicate that, compared to random selection of chimeras, including an analysis of copulatory plugs to set chimeras for breeding can help to reduce costs, minimize time, and facilitate research for projects requiring the production, selection, breeding, and testing of chimeras to generate gene-targeted mice.     

Sex differentiation and germ cell production in chimeric pigs produced by inner cell mass injection into blastocysts

This study aimed at collecting background knowledge for chimeric pig production. We analyzed the genetic sex of the chimeric pigs in relation to phenotypic sex as well as to functional germ cell formation. Chimeric pigs were produced by injecting Day 6 or Day 7 inner cell mass (ICM) cells into Day 6 blastocysts. Approximately 20% of the piglets born from the injected blastocysts showed overt coat color chimerism regardless of the embryonic stage of donor cells. The male:female sex ratio was 7:2 and 6:1 in the chimeras derived from Day 6 and Day 7 ICM cells, respectively, showing an obvious bias toward males. When XX donor cells were injected into XY blastocysts at the same embryonic stage, the phenotypic sex of the resulting chimera was male with no germ-line cells formed from the donor cell lineage. On the other hand, when the donor was XY and the recipient blastocyst was XX, the phenotypic sex of the chimera was male, and germ-line cells were derived only from the donor cells. The combination of XY donor cells and XY blastocysts produced some chimeras in which the donor cell lineage did not contribute to germ-line formation even when it appeared in coat color. When the embryonic stage of the donor was advanced by 1 day in the XY-XY combination, 100% of the germ-line cells of the chimeras were derived from the donor cell lineage. These data showed that characteristics of sex differentiation and germ cell formation in chimeric pigs are similar to those in chimeric mice.     

The genetics of coat colors in the mongolian gerbil (Meriones unguiculatus)

Genetic studies demonstrated three loci controlling coat colors in the Mongolian gerbil. F1 hybrids of white gerbils with red eyes and agouti gerbils with wild coat color had the agouti coat color. The segregating ratio of agouti and white in the F2 generation was 3:1. In the backcross (BC) generation (white x F1), the ratio of the agouti and white coat colors was 1:1. Next, inheritance of the agouti coat color was investigated. Matings between agouti and non-agouti (black) gerbils produced only agouti gerbils. In the F2 generation, the ratio of agouti to non-agouti (black) was 3:1. There was no distortion in the sex ratios within each coat color in the F1, F2 and BC generations. This indicated that the white coat color of gerbils is governed by an autosomal recessive gene which should be named the c allele of the c (albino) locus controlling pigmentation, and the agouti coat color is controlled by an autosomal dominant gene which might be named the A allele of the A (agouti) locus controlling pigmentation patterns in the hair. The occurrence of the black gerbil demonstrated clearly the existence of the b (brown) locus, and it clearly indicated that the coat colors of gerbils can basically be explained by a, b, and c loci as in mice and rats.     

Chimeric drift in allophenic mice: Analysis of changes in red blood cell and white blood cell populations in C57BL/6 ↔ A mice

Fifteen allophenic mice of the type C57BL/6 ? A were quantitatively analyzed for changes in their peripheral white blood cell composition and hemoglobin composition with age. It was found that $\text{7}\text{15}$ or 47% of the mice showed significant changes, termed “chimeric drift,” in one or the other of these parameters. The seven mice showing chimeric drift were classified as unstable chimeras, as opposed to the eight apparently stable chimeras. Chimeric drift was observed in the direction of either parental type, or back and forth, and was found to be independent of the coat color, age, or sex of the mouse. There was an excellent correlation of peripheral white blood cell and hemoglobin compositions of the stable chimeras. However, the unstable chimeras often showed a marked discordance of these two markers.     

The pleiotropic effect of selection for behavior on coat color in grey rats (Rattus norvegicus)

The effects of selection for a type of behavior relative to humans (tame and aggressive) on the intensity of coat color in agouti rats with the AAHH genotype were studied. Animals that were not under selection for behavior (wild animals) were used as the control. Morphometric analysis of the hair parameters that influence the intensity of coat color demonstrated that, on the one hand, polymorphism in the main coat color exists in the population of wild agouti rats, that is, both light and dark agouti animals exist. On the other hand, it was demonstrated that selection for a type of behavior in rats is accompanied by selection of animals that differ in the intensity of the main genetically identical coat color. Dark-colored animals are more prevelent among the aggressive animals, while light-colored animals prevail among tame animals. The association of the effects of selection for behavior with the modification of coat color is probably caused by the presence of common neurohormonal mechanisms for the regulation of these processes.     

The effect of methyl-containing supplements during pregnancy on the phenotypic modification of offspring hair color in rats

The effect of methyl supplements to the diet of pregnant homozygous (AAHH) female rats with agouti coat color mated with homozygous (aahh) males on the phenotypic modification of the coat color of their heterozygous offspring (AaHh) has been studied. Comparative morphological analysis of the main parameters of hair that determine coat color, including the total length of hairs of different types and the length of the upper black (eumelanin) and light (pheomelanin) parts of awn hairs has been performed. The pattern of pigment granule distribution among hair layers has been analyzed. The melanin content of the hair has been determined using electron spin resonance (ESR). Although all offspring have a typical agouti coat color (alternating black and light portions of hair), 39% of them have a darker coat color than control and other experimental rats have. The main differences between the offspring with darkened and standard coat colors are accounted for by the ratio between the eumelanin and pheomelanin portions of awn hairs. In darkened offspring, this ratio is significantly higher than in control rats. The possible mechanisms of the phenotypic modification of agouti coat color in experimental animals are discussed.     

ES细胞（MESPU13）嵌合体小鼠的GPI分析

为了评判小鼠ＥＳ细胞系ＭＥＳＰＵ１３的分化潜能,我们对１９只嵌合小鼠的心、肝、脾、肺、肾、胰腺、生殖腺、肌肉和血液的ＧＰＩ（磷酸葡萄糖异构酶）进行了分析。在这些样品中,来源于ＥＳ细胞的Ａ型条带的检出情况和小鼠的毛色嵌合率成正比关系。当毛色嵌合率低于４０％时,除了少数小鼠的肾脏外,没有看到Ａ型的条带。当毛色嵌合率大于８５％时,几乎所有的器官组织都检测到Ａ型条带,显示了ＥＳ细胞在发育形成内、中、外胚层的细胞方面具有很高的分化潜能。另外,在毛色嵌合率大于８５％的其中的６只嵌合鼠的肌肉中,只观察到Ａ型的条带,表明这些肌肉只单独来源于ＥＳ细胞。     

The effect of methyl supplements during pregnancy on the phenotypic modification of offspring agouti coat color in rats

The effect of methyl supplements to the diet of pregnant homozygous (AAHH) female rats with agouti coat color mated with homozygous (aahh) males on the phenotypic modification of the coat color of their heterozygous offspring (AaHh) has been studied. Comparative morphological analysis of the main parameters of hair that determine coat color, including the total length of hairs of different types and the length of the upper black (eumelanin) and light (pheomelanin) parts of awn hairs has been performed. The pattern of pigment granule distribution among hair layers has been analyzed. The melanin content of the hair has been determined using electron spin resonance (ESR). Although all offspring have a typical agouti coat color (alternating black and light portions of hair), 39% of them have a darker coat color than control and other experimental rats have. The main differences between the offspring with darkened and standard coat colors are accounted for by the ratio between the eumelanin and pheomelanin portions of awn hairs. In darkened offspring, this ratio is significantly higher than in control rats. The possible mechanisms of the phenotypic modification of agouti coat color in experimental animals are discussed.     

Suppression of the antibody response to type III pneumococcal polysaccharide with antigen coupled to syngeneic lymphoid cells

Nine allophenic mice of the type C57BL/10Sn … A were analyzed quantitatively, at weekly intervals over a period of 6 weeks, for the relative parental contributions to their red blood cell and white blood cell populations. It was found that four of the mice showed a significant change (termed “chimeric drift”) in the parental composition of their peripheral white blood cells, as determined by cytotoxicity testing. Six of the mice analyzed showed chimeric drift in their red blood cell population, as determined by hemoglobin analysis on isoelectric focusing gels. The isoelectric points of the hemoglobins of six inbred strains of mice were determined as an outgrowth of this study. Chimeric drift was observed in the direction of either parental cell type, and was found to be independent of the coat color, age, or sex of the mice.     

The production of chimeric rats and their use in the analysis of the hooded pigmentation pattern

New, improved media and procedures for making rat chimeric embryos and culturing them in vitro have been developed. We have produced 27 rat chimeras: 20 males and 7 females. This ratio of males to females is consistent with that seen in mouse chimeras, suggesting that rat sex chimeras develop as phenotypic males. By aggregating embryos containing appropriate genetic markers for pigment cell differentiation, it is possible to produce chimeras that elucidate the site of action of the hooded gene. The coat color patterns of black ? black hooded chimeras display a white belly spot. In black ? albino hooded chimeras, small patches of white hair appear on the head and a large white spot occurs on the belly. Black ? agouti hooded chimeras display both agouti and nonagouti pigmentation over the entire surface of the chimera. These animals are fully pigmented with no white spots. In black ? albino non-hooded chimeras, rather small irregular patches of black and white hairs are distributed throughout the pelage. Histological examination of sections of hair follicles obtained from the white areas in the head of black ? albino hooded chimeras revealed amelanotic melanocytes. On the other hand, hair bulbs from the white belly spots do not contain any such melanocytes. Thus the white hairs of the head are due to the presence of albino melanocytes, but the white hairs of the belly are due to the total absence of melanocytes. All these observations are consistent with the conclusion that the hooded gene acts within melanoblasts, probably to retard their migration from the neural crest and/or to prevent their entrance into the hair follicles of the white areas of hooded rats.     

Quantitative estimation of chimerism in mice using microsatellite markers

An embryonic stem cell line was established from SV129 mouse blastocysts and used to generate chimeric mice by injection into OF1 blastocysts; 18 out of the 30 resulting offspring appeared chimeric as judged from their coat color patterns, and 3 of the 13 males proved to be germ-line chimeras as they transmitted the SV129 agouti phenotype to all or part of their offspring. The degree of chimerism of these males was evaluated for different tissues using polymorphic microsatellite markers amplified by the polymerase chain reaction. It was shown that these new markers can be effectively used to quantitatively estimate levels of chimerism. The CKMM (creatine kinase, muscle) microsatellite system was used to distinguish the SV129 from the OF1 genotype. In all performed tests, the correlation between DNA ratio and signal ratio, expressed as a base 10 logarithm, was shown to exceed or equal 0.98 for known DNA ratios (SV129/OF1) ranging from 1/99 to 99/1. Linear calibration methods were used to predict the % SV129 DNA of a test sample based on the obtained signal ratio. The accuracy of the prediction was evaluated by performing repeated measurements. Differences among three repeated estimates ranged from 2 to 17% for a given sample. Microsatellite systems should be very useful to monitor chimerism involving strains that can not be discerned with coat color or biochemical markers. This will be particularly important when ES methodology becomes available in species other than mice. © 1993 Wiley-Liss, Inc.     

远交系小鼠胚胎干细胞系的建立及嵌合鼠的获得

ＥＳ细胞（ＥｍｂｒｙｏｎｉｃＳｔｅｍＣｅｌｌｓ）是来源于小鼠早期胚胎的多潜能干细胞,它可以在体外大量培养。并以单细胞的形式注射到早期胚胎里,发育为嵌合体。到目前为止,通常使用的１２９小鼠品系是来源于近交系（ｉｎｂｒｅｄ）小鼠的胚胎．与之相比,远交系小鼠应当具有较强的生命力和抗病能力。曾有人报道过建成了远交系小鼠胚胎干细胞系,但是尚没有见到获得嵌合鼠的报道。有人甚至认为：由于不同品系小鼠所具有的遗传背景不同,有的小鼠不能建成ＥＳ细胞系。最近,本实验室在这方面做了有益的探索,成功地建成了远交系小鼠胚胎干细胞系,并在这里报导首例用远交系小鼠胚胎干细胞系培育成功嵌合体小鼠。采用源于Ｓｗｉｓｓ小鼠远交群的昆明（ＫＭ）品系小鼠囊胚建成了三个小鼠胚胎干细胞系（ＫＥ１．ＫＥ２．ＫＥ５）。核型正常率均达到７０％以上。自第八代起分批冻存,复苏后,培养至第１２代,消化成单细胞,通过囊胚显微注射,将其注射到６１５品系小鼠胚胎。在幸存的幼鼠中获得了一只来源于ＫＥ１细胞的嵌合鼠（Ｔａｂｌｅ１）．其毛色表现为受体鼠（６１５）的白色中嵌合有供体鼠（ＫＭ）的黑褐色（ＰｌａｔｅＩ－Ａ）．嵌合鼠与受体鼠的杂交后代鼠中仍然出现了受体鼠的毛色类型（     

Maternal methyl supplements affect the phenotypic variation of the <Emphasis Type="Italic">agouti</Emphasis> gene in the offspring of rats with different behavioral types

The effects of selection of agouti rats (with genotype AAHH) on the tame and aggressive behavior and dietary methyl given to females from the eighth day of pregnancy to the fifth day after the birth of the offspring on the intensity of the agouti coat color in the offspring have been studied. The morphometric parameters of hair determining the darkness of the agouti color (the total length of guard hairs, the lengths of their eumelanin end and pheomelanin band, the ratio between the lengths of the eumelanin and pheomelanin portions of the hair, the total length of the awn hairs, and the relative length of their widened “lanceolate” upper end) have been compared. It has been found that selection of agouti rats for aggressive behavior is accompanied by darkening of the coat color compared to tame rats due to an increase in the ratio of the length of the black eumelanin end of the guard hairs to the length of the yellow pheomelanin band. Methyl-containing additives to the diet of females affect the intensity of the agouti coat color in the offsprings with both types of behavior, but to different extents. Aggressive offspring is more sensitive to the mother’s methyl-containing diet: the percentage of animals that are darker than control rats is higher among aggressive animals than among tame ones due to a greater increase in the ratio between dark and light portions of hairs. The possible mechanisms of differences in the phenotypic modifications of coat color in control and experimental agouti rats with different types of behavior are discussed.     

Cell mixing in the spinal cords of mouse chimeras.

With the aim of determining whether there is significant cell mixing during development of the spinal cord, experimental chimeric mice containing two genetically distinct cell populations were produced by aggregating BALB/c or BALB/c x LPT hybrid embryos with C3H/HeN embryos. The BALB/c and LPT hybrid spinal cord cells were distinguished histochemically from the C3H/HeN spinal cord cells by using beta-glucuronidase as an independent cell genotype marker. BALB/c and LPT hybrid cells have high levels of beta-glucuronidase activity, while the C3H/HeN cells have low levels. The spinal cords of the chimeras were dissected out regionally (i.e., cervical, thoracic, and lumbar areas) and were sectioned serially. Each region was then analyzed by scoring large- and medium-sized neuronal cell bodies (greater than or equal to 10 microns) whose genotypes were distinguished by their beta-glucuronidase levels. Observations of seven chimeric mice, with coat colors that varied from one extreme (5% albino) to the other (90% albino), suggest that each chimeric spinal cord is a relatively homogeneous population throughout its length. On average only 4 to 5 percentage point differences were observed when comparing left-right, cranial-caudal, and dorsal-ventral regions within a given chimera. The cell mixing, however, is not total, and regional variations were noted. Maximum left-right differences between different spinal cord levels never exceeded 18 percentage points, while in the entire cord the maximum left-right difference was 11 percentage points. When considering dorsal-ventral differences, 18 and 15 percentage points were observed within the spinal cord levels and the entire cord, respectively. However, when comparisons were made between smaller subregions (e.g., right-dorsal-cervical vs left-ventral-lumbar), larger differences of up to 30 percentage points were observed. In addition, the genotype proportions in the spinal cord were closely correlated with the visually estimated proportions of coat color genotypes.     

Mouse trisomy 16 as an animal model of human trisomy 21 (Down syndrome): production of viable trisomy 16 diploid mouse chimeras

We have previously proposed that mice trisomic for chromosome 16 will provide an animal model of human trisomy 21 (Down syndrome). However, the value of this model is limited to some extent because trisomy 16 mouse fetuses do not survive as live-born animals. Therefore, in an effort to produce viable mice with cells trisomic for chromosome 16, we have used an aggregation technique to generate trisomy 16 diploid (Ts 16 2n) chimeras. A total of 79 chimeric mice were produced, 11 of which were Ts 16 2n chimeras. Seven of these Ts 16 2n mice were analyzed as fetuses, just prior to birth, and 4 were analyzed as live-born animals. Unlike nonchimeric Ts 16 mouse fetuses which die shortly before birth with edema, congenital heart disease, and thymic and splenic hypoplasia, all but 1 of the Ts 16 2n animals were viable and phenotypically normal. The oldest of the live-born Ts 16 2n chimeras was 12 months old at the time of necropsy. Ts 16 cells, identified by coat color, enzyme marker, and/or karyotype analyses, comprised 50-60% of the brain, heart, lung, liver, and kidney in the 7 Ts 16 2n chimeric fetuses and 30-40% of these organs in the 4 live-born Ts 16 2n animals. Ts 16 cells comprised an average of 40% of the thymus and 80% of the spleen in the Ts 16 2n chimeras analyzed as fetuses, with no evidence of thymic or splenic hypoplasia. However, we observed a marked deficiency to Ts 16 cells in the blood, spleen, thymus, and bone marrow of live-born Ts 16 2n chimeras as compared to 2n 2n controls. These results demonstrate that although the Ts 16 2n chimeras were, with one exception, viable and phenotypically normal, each animal contained a significant proportion of trisomic cells in a variety of tissues, including the brain. Furthermore, our results suggest that although the abnormal development of Ts 16 thymus and spleen cells observed in Ts 16 fetuses is largely corrected in Ts 16 2n fetuses, Ts 16 erythroid and lymphoid cells have a severe proliferative disadvantage as compared to diploid cells in older live-born Ts 16 2n chimeras. Ts 16 2n chimeric mice will provide a valuable tool for studying the functional consequences of aneuploidy and may provide insight into the mechanisms by which trisomy 21 leads to developmental abnormalities in man.     

Pericellular coat of chick embryo chondrocytes: structural role of hyaluronate

Chondrocytes produce large pericellular coats in vitro that can be visualized by the exclusion of particles, e.g., fixed erythrocytes, and that are removed by treatment with Streptomyces hyaluronidase, which is specific for hyaluronate. In this study, we examined the kinetics of formation of these coats and the relationship of hyaluronate and proteoglycan to coat structure. Chondrocytes were isolated from chick tibia cartilage by collagenase-trypsin digestion and were characterized by their morphology and by their synthesis of both type II collagen and high molecular weight proteoglycans. The degree of spreading of the chondrocytes and the size of the coats were quantitated at various times subsequent to seeding by tracing phase-contrast photomicrographs of the cultures. After seeding, the chondrocytes attached themselves to the tissue culture dish and exhibited coats within 4 h. The coats reached a maximum size after 3-4 d and subsequently decreased over the next 2-3 d. Subcultured chondrocytes produced a large coat only if passaged before 4 d. Both primary and first passage cells, with or without coats, produced type II collagen but not type I collagen as determined by enzyme-linked immunosorbent assay. Treatment with Streptomyces hyaluronidase (1.0 mU/ml, 15 min), which completely removed the coat, released 58% of the chondroitin sulfate but only 9% of the proteins associated with the cell surface. The proteins released by hyaluronidase were not digestible by bacterial collagenase. Monensin and cycloheximide (0.01-10 microM, 48 h) caused a dose-dependent decrease in coat size that was linearly correlated to synthesis of cell surface hyaluronate (r = 0.98) but not chondroitin sulfate (r = 0.2). We conclude that the coat surrounding chondrocytes is dependent on hyaluronate for its structure and that hyaluronate retains a large proportion of the proteoglycan in the coat.     

Chimeric drift in blood erythrocyte population in BALB/c----C57BL/10 and BALB----B10.D2 mice

Genotypic composition of the erythrocyte population of peripheral blood in 16 aggregation chimeras: BALB/c (H-2dd)----C57BL/10(H-2bb) and BALB/c(H-2dd)----B10.D2(H-2dd) was studied during 10 months. The proportion of cells of parental components was defined visually in the coat and by electrophoresis of allozyme variants at the Gpi-1 locus in blood. The similar increase of blood cells percentage was observed in blood of both types of chimeras with age. In chimeras the skin grafts of both parental types survive. Chimeric drift is not caused by H-2 haplotypes differences between cells of two strains or disturbance of immunological tolerance in the chimeric mice. We propose that chimeric drift results from interaction of hemopoietic cells of different strains in early stages of hemopoiesis.     

Somatic and germ cell chimerism in chimeric mice between strains of high litter size and regular litter size

CFO is an inbred strain of mice showing a high litter size. The high fertility of CFO is due mainly to a very low embryonic death rate during uterine development. C57BL and 129 strains are characterized by regular litter size. Crosses were made and CFO----C57BL and CFO----129 chimeras were produced. In CFO----C57BL mice, coat color of the C57BL predominated over that of CFO; internal chimerism except for that of the gonads was observed to be in the same proportion as the two genotypes, but the genotypic component of the gonads was almost entirely CFO. Germ cells undergoing gametogenesis in the CFO----C57BL mice were almost all derived from the CFO genotype, and the chimeric females showed high fertility just as did the CFO females. In the CFO----129 mice no obvious skewing toward one genotype was observed in the coat color, but the germ cells undergoing oogenesis in the two types of chimeric females were recognizable as nearly all of the 129 genotype but with the females showing the same high fertility as do the CFO females. This fact suggests that the genotypes of germ cells in the ovary or in developing embryos do not influence fertility, but rather that the litter size is controlled mainly by the uterine environment.     

Phylogeny of lion tamarins (Leontopithecus spp) based on interphotoreceptor retinol binding protein intron sequences

The evolutionary relationships of the lion tamarins (Leontopithecus) were investigated using nuclear interphotoreceptor retinol binding protein (IRBP) intron sequences. Phylogenetic reconstructions strongly support the monophyly of the genus, and a sister relationship between the golden lion tamarin, Leontopithecus rosalia, and the black lion tamarin, L. chrysopygus, to the exclusion of the golden-headed lion tamarin, L. chrysomelas. The most parsimonious evolutionary reconstruction suggests that the ancestral lion tamarin and the common ancestor of L. rosalia and L. chrysopygus had predominantly black coats. This reconstruction is not consistent with a theory of orthogenetic evolution of coat color that was based on coat color evolution in marmosets and tamarins. An alternative reconstruction that is consistent with metachromism requires that ancestral lion tamarins had agouti hairs.